Exogenous Auxin and N-1 -Naphthylphthalamic Acid Effects on Populus deltoides Xylogenesis

A method was developed for evaluating the empirical alterationof xylem vessel differentiation in the central leaf trace ofPopulus deltoides, a species that exhibits helical phyllotaxis.Effects of experimental treatments for a period of six plastochronswere evaluated by vessel parameter ratios = 2.P_T/ (P_T+1 + P_T–1),where P was either vessel number or mean transverse vessel areameasured at mid-intern ode at Leaf Plastochron Indices of T– 1, T, and T + 1. Excising leaf laminae reduced vesselnumber and mean vessel area in the associated central leaf traceby 50% and 70%, respectively, compared to unexcised laminaecontrols. Replacing excised laminae with a concentration seriesof exogenous indoleacetic acid (IAA) resulted in a 5% increaseper log mol m^–3 of IAA in the number of vessels differentiatingin the associated central leaf traces compared to excised controls.Mean vessel areas within these leaf traces were 50% of thoseof intact leaf traces. No significant effects of different concentrationsof exogenously applied IAA on mean vessel area could be demonstrated.A lanolin paste ring of N-1 -naphthylphthalamic acid (NPA),an auxin transport inhibitor, around the petioles of intactleaves reduced the number of differentiating vessels by 7% andmean vessel area by 29% per log mol m^–3 of NPA comparedto central leaf traces of leaves ringed with plain lanolin paste.The results suggest that NPA treatments may be used to distinguishexperimentally, at least in part, the cell division from thecell enlargement phases of primary xylogenesis within centralleaf traces of P. deltoides stems. Key words: Auxin transport, Vessel area, Vessel number     

Fat Metabolism in Germinating Citrullus vulgaris

A column chromatographic technique, enabling identificationand quantitative estimation of fatty acids, has been employedto study fat metabolism in Citrullus during germination in thelight. This plant is characterized by an unusually rapid disappearanceof storage fat as the cotyledons expand and turn green. In spiteof the high catabolic activity there is no evidence for accumulationof free fatty acids or short-chain fatty acids at this stage.Information on this point derived from acid value or saponificationvalue of the oil is shown to be untrustworthy. Citrullus seed fat contains the following percentages of acids:linoleic 70·6, oleic 7·2, palmitic 10·1,stearic 11·2, and arachidic 0·6, and careful analysishas also revealed small amounts of octadecatrienoic acids, bothconjugated and non-conjugated. All the major acids are brokendown at rates proportionate to the quantities originally present,with the exception of oleic acid which is metabolized somewhatmore rapidly. ‘Linolenic’ acid is synthesized in the expandinggreen cotyledons and the fatty acid composition of the latter,in the late germination stages, resembles that of a green leafand is very different from that of the seed. The results suggest a rapid removal of storage fat from thecotyledons and concomitant formation in small quantity of atypial leaf fat as the new photo-synthetic function develops.     

Cold responses of Arabidopsis mutants impaired in freezing tolerance

Mutants of Arabidopsis thaliana L. (Heynh), characterized asdeficient in their freezing tolerance after cold acclimation,were surveyed for some of the normal responses to cold exposure.In foliar tissue, the coldinducibility of three proteins, thelevels of sucrose and glucose, the fatty acyl composition oflipids, and the accumulation of anthocyanin was examined. Fourmutations (sfr3, sfr4, sfr6, and sfr7) reduced or eliminatedthe accumulation of anthocyanin during cold acclimation. Onemutation (sfr4) prevented the normally cold-induced elevationof sucrose and glucose levels; both sfr4 and another mutation(sfr7) affected fatty acid composition after (and only after)cold acclimation. On the other hand mutations sfr1, sfr2 andsfr5 did not differ significantly from the wild type in anyof the parameters tested, suggesting that they have other, perhapshighly specific, effects on lowtemperature responses. Key words: Arabidopsis thaliana, cold acclimation, freezing tolerance, mutation     

Effect of Thiolactomycin on Lipid Synthesis in Higher Plants

The effect of thiolactomycin (TLM), an inhibitor of type IIfatty acid synthase, on lipid synthesis in greening tissueswas examined. Pulse-chase experiments with Na[1-¹⁴C]acetatefor greening Avena leaves showed that continuous administrationof TLM (100µg/ml) decisively reduced phosphatidylcholine(PC) synthesis from acetate and blocked the subsequent conversionof PC to monogalactocyldiacylglycerol (MGDG), whereas temporaladministration of TLM (100 µ/ml) reduced PC synthesisfrom acetate by only 50% and did not block the conversion ofPC to MGDG. In the reduced PC synthesis, the ratio of oleicto palmitic acid decreased at earlier stages of greening, reflectingmore suppression of oleic acid synthesis. In later greeningstages the modulated fatty acid composition recovered to thenormal composition. In further steps, the fatty acid compositionwas not affected by TLM throughout the greening stages. Greeningof either etiolated Avena leaves or etiolated Brassica cotyledonsin the presence of TLM led to a marked decrease in the contentsof MGDG, digalactosyldiacylglycerol (DGDG) and phosphatidylglycerol(PG), but only a small change in the fatty acid compositionof their lipids. The only inhibition characteristic of TLM wasthe desaturation of palmitic to 3-trans-hexadecenoic acid inAvena leaf PG. These results suggest the presence of a mechanismby which the modulated fatty acid composition of lipids is normalizedin the flow of the synthesis. Electron microscopic observationsshowed that Avena chloroplasts developed into round forms ratherthan normal ellipse forms and the thylakoid membranes of Brassicachloroplasts were abnormally swollen everywhere in the presenceof TLM. Photosynthetic oxygen evolution in both tissues wasnot inhibited. (Received December 26, 1986; Accepted April 24, 1987)     

The Effect of Light Intensity, Day Length, and Temperature on Fatty Acid Synthesis and Desaturation in Vicia faba L.

Some effects of light intensity, day length, and temperatureon the fatty acid composition of the major glycerolipids ofleaves of Vicia faba L. (cv. Giant Windsor) were observed. Increasinglight intensity caused an increase in the relative concentrationsof 16 : 1 in PG and 18 : 3 in MGDG and DGDG. Increasing daylength during growth (and continuous illumination of leaf tissue)had no effect on 16 : 1 in PG but caused a decrease in the 18: 3 content of PG, PC, MGDG, and DGDG. Since the quantitiesof these lipids increased under these conditions, the decreasewas not due to photodestruction but to the differences in therelative rates of biosynthesis and desaturation of fatty acids.Incubation of leaf tissue in the dark for 4 d had little effecton the fatty acid composition of MGDG, DGDG, and PG. Temperaturealso controls fatty acid synthesis and desaturation. Above theoptimum growth temperature (20 °C), the 18 : 3 content ofMGDG, DGDG, PG, and PC decreased. In mature leaf tissue, thedegree of unsaturation of MGDG may be modified upward in responseto temperature changes. When plants were grown at 30 °Cand transferred to 20 °C the level of 18 : 3 in MGDG ofthe leaf tissue increased to levels found in plants grown onlyat 20 °C. The level of 18 : 3 in MGDG does not decreaseas rapidly when plants grown at 20 °C were transferred to30 °C. This suggests that the lower temperature induceddesaturation of 18 : 2 to 18 : 3.     

Vascular Differentiation in the Shoot Apex of Matteuccia struthiopteris

Initial vascular differentiation is generally considered tooccur in procambium. In ferns, however, a provascular tissueimmediately subjacent to the promeristem has been suggestedas an initial stage within which the procambium is subsequentlyformed. In contrast to this interpretation, a zonation conceptapplied in ferns recognizes a promeristem consisting of severallayers of cells in which no differentiation takes place. Thisstudy demonstrates that the shoot apex of Matteuccia struthiopterishas one cell layer of promeristem. Immediately subjacent tothe promeristem is the provascular tissue surrounding a centralgroup of pith mother cells. The developmental continuity betweenthe provascular tissue and the mature vascular tissue, and betweenthe pith mother cells and the pith, through transitional stages,indicates that the initial differentiation of vascular tissueand pith takes place in this prestelar tissue. The continuityof vascular differentiation in the area confronting young leavesor incipient leaf positions is interrupted by the formationof leaf gap initials. Developing leaves thus begin to exertinfluence on the vascular system at the prestelar stage. Smallprotoxylem elements with helical cell wall thickening, and distinctiveprotophloem elements are present in the leaf traces, but endabruptly near the junction regions of leaf traces to the meristele.Copyright1994, 1999 Academic Press Initial vascular differentiation, provascular tissue, pith mother cells, shoot apex, Matteuccia struthiopteris     

Physiology of the parasitic association between maize and witchweed (Striga hermonthica): is ABA involved?

Striga hermonthica (Del.) Benth. is an obligate hemiparasiticangiosperm which can cause severe losses of yield in cerealcrops in the semi-arid tropics. The effects of this parasiteon the growth and stomatal conductance of three varieties ofmaize (Zea mays L.) during the first 6 weeks of the associationhave been studied. From 24 d after planting (DAP), infectedplants were significantly shorter than uninfected controls.When the plants were harvested 45 DAP, infected plants had fewerfully expanded leaves, less leaf biomass and less pseudo-stembiomass than uninfected controls. However, the parasitized plantshad more root biomass and hence a higher root:shoot ratio thanuninfected controls. The stomatal conductance of infected hostswas severely inhibited by comparison with that in uninfectedplants. The possibility that abscisic acid (ABA) may be involved inthe regulation of the parasitic association was investigated.ABA concentrations in leaf tissue of maize (cv. Cargimontana)and S. hermonthica were determined by radioimmunoassay. Whilethere was a difference between cultivars in the extent of theresponse, the concentrations of ABA were significantly higherin infected maize plants than in the uninfected controls. InS. hermonthica, leaf tissue ABA concentration was found to bean order of magnitude higher than in the host leaf tissue. Detachedleaves of S. hermonthica which were dehydrated at room temperatureuntil they had lost 10–20% of their fresh weight containedthree times the ABA concentration of control leaves. This suggeststhat leaves of S. hermonthica can synthesize or re-mobilizeABA in response to water deficit. It is not yet known whetherthis contributes to the higher concentration in infected hosts,but the results suggest that ABA has a role in this parasiticassociation. Key words: Striga hermonthica, abscisic acid, growth, parasitic angiosperm, stomatal conductance     

Lipids in Acanthodiaptomus denticomis during starvation and fed on three different algae

Variations in the levels of triglycerides, wax esters and polarlipids were determined in adults of the calanoid copepod Acanthodiaptomusdenticornis when freshly caught, starved or fed on the followingalgae: Anabaena spiroides, Cyclotella pseudostelligera and Pediastrumduplex. Over 7 days starvation, triglycerides and wax esterswere almost entirely used up by the copepods. Subsequent feedingover 20 days partially restored triglycerides but restored onlya relatively small fraction (<20%) of wax esters in the animals.Differences in the lipid restoration were found: the restoredtriglyceride level was higher in animals feeding on Cyclotellapseudostelligera or Pediastrum duplex than in those feedingon Anabaena spiroides. Fatty acid composition of neutral lipidswas closely linked to fatty acid composition of algae. The resultssuggest that lipid and fatty acid contents of Acanthodiaptomusdenticornis are good indices of the copepod's nutritional statusand short-term (0–20 days) feeding history.     

Analysis of Lipids of Citrullus lanatus (cv. Sugar baby) During Seed Germination and Seedling Growth

Changes in the dry weight (dry wt.), total and neutral lipids,and fatty acid composition were determined in the cotyledonsand axis of Citrullus lanatus cv. Sugar baby seedlings duringtheir first 12 d growth in the dark, at 25 ? 1 ?C. The major stored reserves were mobilized between days 3 and8. The lipid concentration after day 4 decreased rapidly inthe cotyledons. On the first day the lipid concentration inthe axis was higher than in the cotyledons but decreased rapidlyand from day 5 up to the end of the experiments it remainedat very low values. In the cotyledons, the change in the fattyacid composition was relatively small compared to the significantchange observed in the axis. The neutral lipids of the cotyledonsdecreased sharply between days 2 and 6 while their fatty acidcomposition suffered no significant change. The axis, comparedto the cotyledons, contained a small but concentrated amountof neutral lipids, which decreased up to day 6. Thereafter,an increase was observed. The fatty acid composition of theaxis neutral lipids changed significantly, linoleic and oleicacid decreased while palmitic and linolenic acid increased. Key words: Citrullus lanatus, seed germination, seedling growth, lipids, fatty acids     

Cell Lineage of Vein Formation in Variegated Leaves of the C4Grass Stenotaphrum secundatum

Clonal analysis of variegated leaves of the C₄grass, Stenotaphrumsecundatum, indicates that invasions among meristematic layersoccur during the organogenetic stage of leaf development, resultingin long, broad white and green stripes. These layer invasionscease prior to the second phase of leaf development when delimitationof leaf regions occurs. Vein precursors mostly arise duringthe second phase, so that procambial strand formation is superimposedon the lineage makeup of earlier-formed tissue. Anatomical evidenceindicates that procambium arises through formative divisionswithin ground tissue of leaf primordia and that each strandis derived from a variable number (one–four) of groundmeristem precursors. If a developing vein straddles the boundarybetween previously-formed green and white sectors, then themature vein is half green and half white, reflecting its mixedcell lineage. In Stenotaphrum, 24.8% of the sectors observedwere bounded by such ‘half veins’. The temporalrelationship of layer invasion and tissue system delimitationin this species supports the view that positional signals aremore important than lineage history in the determination oftissue type. However, analysis of planes of cell division indeveloping veins indicates, that, once formed, procambial strandsare discrete lineage units that extend longitudinally by proliferativedivisions. Thus, lineage restrictions may play an importantrole in the third stage of leaf development, differentiationof tissues and cells, which also includes the maintenance ofcell identity.Copyright 2000 Annals of Botany Company C₄photosynthesis, cell lineage, clonal analysis, leaf development, St. Augustine’s grass,Stenotaphrum secundatum , variegation, vein formation     

Leaf Nucleic Acids:: II. METABOLISM DURING SENESCENCE AND THE EFFECT OF KINETIN

The nucleic acids in the green and in the senescent leaves ofthree types of plant have been studied. High and low molecularweight RNA of the chloroplast is not present in senescent leavesof Xanthium pensylvanicum, but both cytoplasmic and chloroplasticfractions are found in yellow leaves of Vicia faba and Nicotianatabacum. RNA is more rapidly degraded than DNA in the leavesof these plants when they are detached, and kinetin treatmenttemporarily arrests the loss of chlorophyll and nucleic acid.Once X. pensylvanicum leaves are yellow and senescent they cannotbe re-greened, whereas those of Nicotiana spp., and to someextent those of V. faba, can be rejuvenated. We suggest thatthe retention of chloroplast RNA in yellow leaves may be a majorfactor determining their ability to re-green and that the patternof organelle senescence prior to the first stages of leaf autolysisand dehydration is species-specific.     

Hydroxypyruvate Reductase with a Carboxy-Terminal Targeting Signal to Microbodies is Expressed in Arabidopsis

Five Arabidopsis EST cDNA clones of hydroxypyruvate reductase(HPR), a photorespiratory enzyme in leaf peroxisomes, were sequenced.Deduced amino acid sequences revealed that HPR in Arabidopsiscontained the carboxy-terminal targeting signal to microbodies.Nucle-otide sequence analysis showed that the cDNA with thelongest insert contained an open reading frame of 1,158 bp whichencoded a polypeptide with 386 amino acids with a calculatedmolecular mass of 42,251 Da. A Southern blot analysis suggestedthat the Arabidopsis HPR gene, like that of the pumpkin HPRgene, exists as a single copy. Two kinds of pumpkin HPR mRNAmight be produced from a single gene by alternative splicing,but the structure of the genomic DNA indicated that the ArabidopsisHPR gene did not undergo alternative splicing. We detected apolypeptide with a molecular mass of 42 kDa in green leavesof Arabidopsis using an HPR-specific antibody. Immunoelectronmicroscopy revealed that Arabidopsis HPR protein was exclusivelylocalized in leaf peroxisomes in green leaves. These resultsindicate that HPR is expressed in a form with a carboxy-terminaltargeting signal to microbodies and is localized in microbodiesin Arabidopsis, suggesting that the differences in the genestructure and the regulation of gene expression of HPR are probablydue to species-specific differences in plants. (Received November 11, 1996; Accepted February 1, 1997)     

Inhibition of Ethylene Production by Fatty Acids in Fruit and Vegetable Tissues

Fatty acids of chain length from C₄ to C₁₂ inhibited ethyleneproduction in wounded albedo tissue of Hassaku (Citrus hassakuHort. ex Tanaka) fruit. Of the fatty acids tested, caprylicacid (C₈) and capric acid (C₁₀) were the most effective. Lauricacid (C₁₂) was less effective, and caproic acid (C₆) and butyricacid (C₄) were the least effective. Caprylic acid at 5 mM markedlyinhibited ethylene production in not only wounded albedo tissueof citrus fruit but also apple (Malus sylvestris Mill.) cortex,tomato (Lycopersicon esculentum Mill.) pericarp, cucumber (Cucumissativus L.) cortex, banana (Musa AAA group Cavendish subgroup)pulp, broccoli (Brassica oleracea L.) floret, spinach (Spinaciaoleracea L.) leaf, lettuce (Lactuca sativa L.) leaf and mungbean (Vigna radiata [L.] Wilczek) hypocotyl. Caprylic acid inhibitedethylene production at the step of conversion of l-aminocyclopropane-l-carboxylicacid to ethylene. The inhibition could be partially relievedby transferring the tissue to caprylic acid-free medium. (Received June 15, 1982; Accepted August 13, 1982)     

Etioplast Development in Dark-grown Leaves of Zea mays L

The ultrastructure of etioplasts and the acyl lipid and the fatty acid composition of sequential 2-centimeter sections cut from the base (youngest) to the top (oldest) of nonilluminated 5-day-old etiolated leaves of Zea mays L., and the acyl lipid and fatty acid composition of the etioplasts isolated from them have been investigated. There is a 2.5-fold increase in the size of the plastids from the base to the tip of the leaf, and an increase both in the size of the prolamellar body and in the length of lamellae attached to it. The etioplasts in the bundle sheath and mesophyll cells of the older, but not the younger leaf tissue, are morphologically distinct. The monogalactosyl and digalactosyldiglycerides, phosphatidylcholine, phosphatidylglycerol, and phosphatidylinositol were the only detectable acyl lipids in the isolated etioplast fractions. Together with phosphatidylethanolamine these were also the major acyl lipids in the whole leaf sections. With increasing age of the leaf tissue, increases occurred in two of the major plastid lipids, monogalactosyldiglyceride and phosphatidylglycerol, while the levels of essentially nonplastid lipids remained constant or declined slightly. The monogalactosyldiglyceride to digalactosyldiglyceride ratio increased from 0.4 to 1.1 in the tissue sections of increasing age and from 0.7 to 1.2 in the etioplasts isolated from them. Similarly, the galactolipid to phospholipid ratio increased from 0.8 to 1.4 in the tissue and from 0.5 to 4.5 in the isolated plastids. In the latter, the proportions of phosphatidylglycerol (as a per cent of total phospholipid) increased from 20 to 41% with increasing age of plastids.

Linolenic acid was the major fatty acid in the total lipid of each of the etioplast fractions, but it was only the major fatty acid in the total lipid of the oldest leaf tissue. Its proportion in both total lipid extracts and individual lipids increased with age. The trans Δ³ hexadecenoic acid was absent from all lipids. The protochlorophyllide content of the tissue increased with age. The results are discussed in relation to the use of illuminated etiolated leaves for studying chloroplast development.

     

Comparison of Glycolipids and Plastids in Callus Cells and Leaves of Alnus and Betula

The fine structure of plastids and fatty acid composition ofglycolipids (e.g. monogalactosyl diacylglycerides, MGDG; digalactosyldiacylglycerides, DGDG) in callus cells of Alnus glutinosa,A. incana and Betula pendula cultured in light was comparedwith that in intact leaves. The tissues were qualitatively verysimilar but a rather high amount oflignoceric acid (24:0) wascharacteristic for the callus of A. incana. This fatty acidwas found only in trace amount in other tissues. Linolenic (18:3)and palmitic (16:0) acids are the most abundant (25–65%and 17–27% respectively) fatty acids in all tissues studied.The proportion of 18:1 and 18:2 was much higher in the calluscompared with corresponding intact leaves, which are especiallyrich (48–65%) in 18:3. In callus cultures a higher proportion(17–19%) of linoleic acid (18:2) is found in both Alnusspecies than in the two callus strains of Betula (9–12%). All leaf and callus samples contained esterified steryl glycosidesand two cerebrosidelike spots in thin-layer chromatography,but they were more prominent in callus cultures than in leaves.The callus cells have plastids with rather well developed thylakoidswhich explains the similarity of the main glycolipid components(MGDG and DGDG) to that of leaves. (Received April 23, 1984; Accepted August 17, 1984)     

Modelling of the Partitioning, Assimilation and Storage of Nitrate within Root and Shoot Organs of Castor Bean (Ricinus communis L.)

An experimentally-based modelling technique was developed todescribe quantitatively the uptake, flow, storage and utilizationof NO₃-N over a 9 d period in mid-vegetative growth of sandcultured castor bean (Ricinus communis L.) fed 12 mol m^–3nitrate and exposed to a mean salinity stress of 128 mol m^–3NaCl. Model construction used information on increments or lossesof NO₃-N or total reduced N in plant parts over the study periodand concentration data for NO₃-N and reduced (amino acid) Nin phloem sap and pressure-induced xylem exudates obtained fromstem, petiole and leaf lamina tissue at various levels up ashoot. The resulting models indicated that the bulk (87%) of incomingnitrate was reduced, 51% of this in the root, the remainderprincipally in the laminae of leaves. The shoot was 60% autotrophicfor N through its own nitrate assimilation, but was oversuppliedwith surplus reduced N generated by the root and fed to theshoot through the xylem. The equivalent of over half (53%) ofthis N returned to the root as phloem translocate and, mostly,then cycled back to the shoot via xylem. Nitrate comprised almosthalf of the N of most xylem samples, but less than 1% of phloemsap N. Laminae of leaves of different age varied greatly inN balance. The fully grown lower three leaves generated a surplusof reduced N by nitrate assimilation and this, accompanied byreduced N cycling by xylem to phloem exchange, was exportedfrom the leaf. Leaf 4 was gauged to be just self-sufficientin terms of nitrate reduction, while also cycling reduced N.The three upper leaves (5–7) met their N balance to varyingextents by xylem import, phloem import (leaves 6 and 7 only)and assimilation of nitrate. Petioles and stem tissue generallyshowed low reductase activities, but obtained most of theirN by abstraction from xylem and phloem streams. The models predictedthat nodal tissue of lower parts of the stem abstracted reducedN from the departing leaf traces and transferred this, but notnitrate, to xylem streams passing further up the shoot. As aresult, xylem sap was predicted to become more concentratedin N as it passed up the shoot, and to decrease the ratio ofNO₃-N to reduced N from 0·45 to 0·21 from thebase to the top of the shoot. These changes were reflected inthe measured N values for pressure-induced xylem exudates fromdifferent sites on the shoot. Transfer cells, observed in thexylem of leaf traces exiting from nodal tissue, were suggestedto be involved in the abstraction process. Key words: Ricinus communis, nitrogen, nitrate, nitrate reduction, partitioning, phloem, xylem, flow models     

Ethylene evolution in marine algae and a proteinaceous inhibitor of ethylene biosynthesis from red alga

Fronds of marine algae, especially green alga, Codium latum,and red alga, Porphyra tenera, evolved a quantity of ethylenewhen IAA was exogenously applied, while brown alga, Padina arborescens,evolved only a little. Propionic acid, when added together withIAA, noticeably enhanced IAA-induced ethylene evolution in P.tenera and P. arborescens. This evolution was also enhancedby added acrylic acid in P. arborescens but not in P. tenera.It was promoted by methionine, though only at a high concentration(0.1 M), in P. tenera but not in P. arborescens. The rate ofethylene evolution was highest at 12?C among the incubationtemperatures tested of 5, 12 and 15?C. The conversion of ¹⁴C-3-methionineto radioactive ethylene in P. tenera was remarkably inhibitedby a proteinaceous inhibitor from P. tenera. ¹Present address: Division of Environmental Biology, NationalInstitute for Environment, Yatabe, Ibaraki, Japan. (Received May 27, 1976; )     

Intracellular Silica Deposition in Immature Leaves in Three Species of the Gramineae

The formation of solid, discrete deposits of opaline silicawithin the cell lumen of leaf tissues is reported in speciesrepresenting three subfamilies of the Gramineae; the preparationof a silica-minimal nutrient solution is discussed. Opal phytolithnumbers are related to tissue age and to two external silicaconcentrations for tiller leaves over a period of 32 days followingbud initiation. Variations in silica deposition patterns among the individualleaves of a homologous series on the shoot apex are relatedto differential growth-rates. During ontogeny, deposition occursin an ordered sequence of cell types related to the basipetalmaturation gradient within the leaf. Initial deposition wasdetected in silica cells (idioblasts) of imbricated, bud leavesof Sieglingia decumbens, 1 mm long; phytoliths are confinedto these cells in expanding, basal portions of the leaf. Phytolithcounts/sq mm of epidermis vary with the degree of long-cellexpansion. The error is reduced by expressing silicificationas the number of phytoliths/100 silica cells. Post-expansiondeposition was initiated in epidermal long cells of the leafblade tip. The higher silica concentration resulted in a morerapid utilization of available deposition sites and larger phytoliths(P = 0.001). A passive cell influx of silicic acid is discussedin relation to cytodifferentiation.