Sucrose Phosphate Is Not Transported into Vacuoles or Tonoplast Vesicles from Red Beet (Beta vulgaris) Hypocotyl

Tonoplast vesicles and vacuoles isolated from red beet (Beta vulgaris L.) hypocotyl accumulated externally supplied [¹⁴C]sucrose but not [¹⁴C]sucrose phosphate despite the occurrence of sucrose phosphate phosphohydrolytic activity in the vacuole. The activities of sucrose synthase and sucrose phosphate synthase in whole cell extracts were 960 and 30 nanomoles per milligram protein per minute, respectively; whereas, no sucrose synthesizing activity was measured in tonoplast preparations. The results obtained in this investigation are incompatible with the involvement of sucrose phosphate synthase in the process of sucrose synthesis and accumulation in the storage cells of red beet.     

Selective production of sealed plasma membrane vesicles from red beet (Beta vulgaris L.) storage tissue

Modification of our previous procedure for the isolation of microsomal membrane vesicles from red beet (Beta vulgaris L.) storage tissue allowed the recovery of sealed membrane vesicles displaying proton transport activity sensitive to both nitrate and orthovanadate. In the absence of a high salt concentration in the homogenization medium, contributions of nitrate-sensitive (tonoplast) and vanadate-sensitive (plasma membrane) proton transport were roughly equal. The addition of 0.25 M KCl to the homogenization medium increased the relative amount of nitrate-inhibited proton transport activity while the addition of 0.25 M KI resulted in proton pumping vesicles displaying inhibition by vanadate but stimulation by nitrate. These effects appeared to result from selective sealing of either plasma membrane or tonoplast membrane vesicles during homogenization in the presence of the two salts. Following centrifugation on linear sucrose gradients it was shown that the nitrate-sensitive, proton-transporting vesicles banded at low density and comigrated with nitrate-sensitive ATPase activity while the vanadate-sensitive, proton-transporting vesicles banded at a much higher density and comigrated with vanadate-sensitive ATPase. The properties of the vanadate-sensitive proton pumping vesicles were further characterized in microsomal membrane fractions produced by homogenization in the presence of 0.25 M KI and centrifugation on discontinuous sucrose density gradients. Proton transport was substrate specific for ATP, displayed a sharp pH optimum at 6.5, and was insensitive to azide but inhibited by N'-N-dicyclohexylcarbodiimide, diethylstilbestrol, and fluoride. The Km of proton transport for Mg:ATP was 0.67 mM and the K0.5 for vanadate inhibition was at about 50 microM. These properties are identical to those displayed by the plasma membrane ATPase and confirm a plasma membrane origin for the vesicles.     

Fluid phase and receptor-mediated endocytosis in Paramecium primaurelia by fluorescence confocal laser scanning microscopy

In ciliated protozoa, most nutrients are internalized via phagocytosis by food vacuole formation at the posterior end of the buccal cavity. The uptake of small-sized molecules and external fluid through the plasma membrane is a localized process. That is because most of the cell surface is internally covered by an alveolar system and a fibrous epiplasm, so that only defined areas of the cell surface are potential substance uptake sites. The purpose of this study is to analyze, by fluorescence confocal laser scanning microscopy, the relationship between WGA (Triticum vulgaris agglutinin) and dextran internalization in Paramecium primaurelia cells blocked in the phagocytic process, so that markers could not be internalized via food vacuole formation. WGA, which binds to surface constituents of fixed and living cells, was used as a marker for membrane transport and dextran as a marker for fluid phase endocytosis. After 3 min incubation, WGA-FITC is found on plasma membrane and cilia, and successively within small cytoplasmic vesicles. After a 10-15 min chase in unlabeled medium, the marked vesicles decrease in number, increase in size and fuse with food vacuoles. This fusion was evidenced by labeling food vacuoles with BSA-Texas red. Dextran enters the cell via endocytic vesicles which first localize in the cortical region, under the plasma membrane, and then migrate in the cytoplasm and fuse with other endocytic vesicles and food vacuoles. When cells are fed with WGA-FITC and dextran-Texas red at the same time, two differently labeled vesicle populations are found. Cytosol acidification and incubation in sucrose medium or in chlorpromazine showed that WGA is internalized via clathrin vesicles, whereas fluid phase endocytosis is a clathrin-independent process.     

H-ATPase Activity from Storage Tissue of Beta vulgaris: I. Identification and Characterization of an Anion-Sensitive H-ATPase

Microsomal membranes isolated from red beet (Beta vulgaris L.) storage tissue were found to contain high levels of ionophore-stimulated ATPase activity. The distribution of this ATPase activity on a continuous sucrose gradient showed a low density peak (1.09 grams per cubic centimeter) that was stimulated over 400% by gramicidin and coincided with a peak of NO₃⁻-sensitive ATPase activity. At higher densities (1.16-1.18 grams per cubic centimeter) a shoulder of gramicidin-stimulated ATPase that coincided with a peak of vanadate-sensitive ATPase was apparent. A discontinuous sucrose gradient of 16/26/34/40% sucrose (w/w) was effective in routinely separating the NO₃⁻-sensitive ATPase (16/26% interface) from the vanadate-sensitive ATPase (34/40% interface). Both membrane fractions were shown to catalyze ATP-dependent H⁺ transport, with the transport process showing the same differential sensitivity to NO₃⁻ and vanadate as the ATPase activity.

Characterization of the lower density ATPase (16/26% interface) indicated that it was highly stimulated by gramicidin, inhibited by KNO₃, stimulated by anions (Cl⁻ > Br⁻ > acetate > HCO₃⁻ > SO₄²⁻), and largely insensitive to monovalent cations. These characteristics are very similar to those reported for tonoplast ATPase activity and a tonoplast origin for the low density membrane vesicles was supported by comparison with isolated red beet vacuoles. The membranes isolated from the vacuole preparation were found to possess an ATPase with characteristics identical to those of the low density membrane vesicles, and were shown to have a peak density of 1.09 grams per cubic centimeter. Furthermore, following osmotic lysis the vacuolar membranes apparently resealed and ATP-dependent H⁺ transport could be demonstrated in these vacuole-derived membrane vesicles. This report, thus, strongly supports a tonoplast origin for the low density, anion-sensitive H⁺-ATPase and further indicates the presence of a higher density, vanadate-sensitive, H⁺-ATPase in the red beet microsomal membrane fraction, which is presumably of plasma membrane origin.

     

Sucrose phosphatase associated with vacuole preparations from red beet, sugar beet, and immature sugarcane stem

The specific phosphatase, sucrose phosphate phosphohydrolase (sucrose phosphatase, EC 3.1.3.24) was present in vacuole preparations from storage tissue of red beet (Beta vulgaris L.), sugar beet (Beta vulgaris L. cultivar Kawemono), and immature sugarcane (Saccharum spp. hybrid, cultivar NCO 310). In red beet vacuole preparations the specific activity of sucrose phosphatase, using the naturally occurring vacuole marker, betanin, as reference, was higher than the specific activity of cytoplasmic markers, phosphoenolpyruvate carboxylase and glucose 6-phosphate dehydrogenase, suggesting that sucrose phosphatase is associated with the vacuoles. High speed centrifugation of lysed vacuoles did not result in precipitation of the enzyme indicating that the enzyme is not tightly bound to the tonoplast. Sucrose phosphatase was more sensitive to inhibition by sodium vanadate and less sensitive to ammonium molybdate than was the nonspecific phosphatase which was also present in the extracts. Sucrose phosphatase might be part of the group translocator proposed recently to operate in the tonoplast of sugarcane and red beet.     

A small scale procedure for the isolation of transport competent vesicles from plant tissues

A microscale method for the isolation of selectively sealed microsomal membrane fractions from plant tissue is presented. The method is based on differential centrifugation in a table top microcentrifuge to accommodate small sample size (10-25 g tissue) and the addition of KI or KCl in the homogenization medium for isolating selectively sealed plasma membrane or tonoplast vesicles. This microscale procedure was found to be useful in isolating membranes from red beet (Beta vulgaris) storage tissue, sugar beet (Beta vulgaris) storage tissue, corn (Zea mays) roots, and soybean (Glycine max) roots. This paper also describes the ability to further purify an enriched red beet plasma membrane fraction on a discontinuous sucrose density gradient, in a microcentrifuge, that is highly competent in ATP-dependent H+-transport. The speed and wide applicability of this procedure make it ideal when a large number of samples need to be processed.     

Sucrose transport in tonoplast vesicles of red beet roots is linked to ATP hydrolysis

Sucrose uptake into tonoplast vesicles, which were prepared from red beet (Beta vulgaris L.) vacuoles isolated by two different methods, was stimulated by MgATP. Using the same medium as for osmotic disruption of vacuoles, membrane vesicles were prepared from tissue homogenates of dormant red beet roots and separated by high-speed centrifugation through a discontinuous dextran gradient. A low-density microsomal fraction highly enriched in tonoplast vesicles could be further purified from contaminating ER vesicles by inclusion of 5 mM MgCl₂ in the homogenization medium. These vesicles were able to transport sucrose in an ATP-dependent manner against a concentration gradient, whereas vesicles from regions of other densities lacked this feature, indicating that ATP stimulation of sucrose uptake took place only at the tonoplast membrane. Sucrose uptake was optimal at pH 7 in the presence of MgATP and could be stimulated by superimposed pH gradients (vesicle interior acidic) in the absence of MgATP, which is consistent with the operation of a sucrose/H⁺-antiporter at the tonoplast. Tonoplast vesicles, obtained in high yield from tissue homogenates of red beet roots, exhibited sugar-uptake characteristics comparable to those of intact vacuoles; these characteristics included similarities in K _m (1.7 mM), sensitivity to inhibitors and specificity for sucrose.Many experiments were carried out at the Experiment Station of the HSPA, Aiea, Hawaii and financed by an NSF grant to Dr. Maretzki and Mrs. M. Thom.     

Mannitol-enhanced, fluid-phase endocytosis in storage parenchyma cells of celery (Apium graveolens; Apiaceae) petioles

We recently demonstrated the occurrence of a sucrose-enhanced, fluid-phase endocytic (FPE) mechanism of nutrient uptake in heterotrophic cells. In the present work, the possible enhancement/induction of FPE by photoassimilates other than sucrose was investigated by measuring the incorporation of the fluorescent endocytosis marker d-TR (dextran-Texas red, 3000 mw) into celery (Apium graveolens) petiole storage parenchyma (CSP), a tissue that transports and accumulates mannitol. Mannitol uptake in these cells is biphasic, with a hyperbolic phase at concentrations below 20 mM and a linear phase above 20 mM external solute concentration. In the absence of mannitol, or in its presence at concentrations within the hyperbolic phase, CSP cells accumulated low levels of d-TR. Conversely, d-TR accumulation by CSP cells was greatly enhanced in the presence of mannitol at concentrations within the linear phase. At high external mannitol concentration, d-TR accumulation was prevented by the endocytic inhibitors LY294002 and latrunculin B. In addition, d-TR uptake was temperature dependent under high mannitol concentration. Microscopic observations revealed that d-TR accumulated in the vacuole. These data support the occurrence of an FPE mechanism in CSP cells that participates in trapping and transport of photoassimilates to the vacuole. The FPE mechanism is enhanced by high mannitol concentrations.     

Immunological Evidence for the Existence of a Carrier Protein for Sucrose Transport in Tonoplast Vesicles from Red Beet (Beta vulgaris L.) Root Storage Tissue

Monoclonal antibodies were raised in mice against a highly purified tonoplast fraction from isolated red beet (Beta vulgaris L. ssp. conditiva) root vacuoles. Positive hybridoma clones and sub-clones were identified by prescreening using an enzyme-linked immunosorbent assay (ELISA) and by postscreening using a functional assay. This functional assay consisted of testing the impact of hybridoma supernatants and antibody-containing ascites fluids on basal and ATP-stimulated sugar uptake in vacuoles, isolated from protoplasts, as well as in tonoplast vesicles, prepared from tissue homogenates of red beet roots. Antibodies from four clones were particularly positive in ELISAs and they inhibited sucrose uptake significantly. These antibodies were specific inhibitors of sucrose transport, but they exhibited relatively low membrane and species specificity since uptake into red beet root protoplasts and sugarcane tonoplast vesicles was inhibited as well. Fast protein liquid chromatography assisted size exclusion chromatography on Superose 6 columns yielded two major peaks in the 55 to 65-kD regions and in the 110- to 130-kD regions of solubilized proteins from red beet root tonoplasts, which reacted positively in immunoglobulin-M(IgM)-specific ELISAs with anti-sugarcane tonoplast monoclonal IgM antibodies. Only reconstituted proteoliposomes containing polypeptides from the 55- to 65-kD band took up [14C]-sucrose with linear rates for 2 min, suggesting that this fraction contains the tonoplast sucrose carrier.     

Characterization of proton and sugar transport at the tonoplast of sweet lime (Citrus limmetioides) juice cells

Citrus fruits accumulate high levels of sucrose and hexoses, although most photoas-similates arrive in the form of sucrose. In sweet limes, faster rates of sugar accumulation take place early in development when sucrose catabolic enzymes are most active. The present investigation was aimed at providing information on the mechanisms of sucrose (and hexose) uptake into the vacuole of cells containing high levels of sucrose hydrolytic activity. Tonoplast vesicles of high purity were isolated in a discontinuous sucrose gradient. The vesicles were capable of forming a pH gradient in the presence of ATP. Both bafilomycin and NO₃⁻ (but not vanadate) inhibited ATP hydrolysis and prevented the formation of the pH gradient, confirming the tonoplast origin. Energized vesicles (either by addition of ATP or by artificial pH gradient) did not accumulate sucrose or hexoses against a concentration gradient. In the presence of either sucrose or hexoses, the established ΔpH; was not disrupted as was the case with tonoplast vesicles from red beet hypocotyl. Therefore, a sucrose/H⁺ (hexose) antiport may not be the mechanism of sucrose and hexose transport into the vacuoles of sweet lime juice cells. The data indicated that sucrose uptake into vacuoles of sweet lime occurs by facilitated diffusion. Hexoses originate from the hydrolytic action of acid invertase on sucrose within the vacuole, and by the action of cytosolic sucrose synthase.     

Evidence for two endocytic transport pathways in plant cells

Intracellular trafficking of endocytic vesicles in eukaryotes varies with the nature of the cargo molecules and the targeted organelle, and proceeds through an intricate network of internal endosomal compartments. However, the path for fluid-phase endocytosis (FPE), the internalization of external solutes from the apoplast via plasmalemma generated vesicles, remains unresolved despite some indication of a direct transport route to the vacuole. To test this hypothesis, we made use of the membrane-impermeable Na-dependent fluorescent marker Coro-Na in combination with the fluorescent membrane marker FM 4-64 and confocal laser scanning microscopy. When protoplasts from sweet lime juice cells were incubated in Na-free solution, FM 4-64, Coro-Na, and 200 mM sucrose, two distinct types of labeled vesicles were evident. A set of vesicles (1 μm in diameter) was intensely labeled with Coro-Na and to a lesser extent with FM 4-64, whereas the second type of 1–7 μm structures appeared exclusively labeled with FM 4-64. These data demonstrate the parallel functioning of two endocytic pathways in plant cells. In one system, a set of small endocytic vesicles merge with the endosome, whereas a separate set of vesicles fuse to form larger vesicles independent from the endosome. Although it is likely that both vesicle systems eventually contribute to solutes reaching the vacuole, given their size (1–7 μm), and based on previous observations of endocytic vesicle formation protruding from the plasmalemma and merging with the vacuole, we conclude that these latter vesicles constitute the primary FPE vesicle system.     

separation and Immunological Characterization of Membrane Fractions from Barley Roots

Tonoplast and plasma membranes (PM) were isolated from barley roots (Hordeum vulgare L. cv California Mariout 72) using sucrose step gradients. The isolation procedure yielded sufficient quantities of PM and tonoplast vesicles that were sealed and of the right orientation to measure ATP-dependent proton transport in vitro. The proteins of the endoplasmic reticulum, tonoplast-plus-Golgi membrane (TG) and PM fractions were separated on sodium dodecyl sulfate gels, and immunoblots were used to test for cross-contamination between the fractions. Proteins that cross-reacted with antibodies to the PM ATPase from corn roots and Neurospora were greatly enriched in the PM fraction, as were proteins that cross-reacted with monoclonal antibodies to an arabinogalactan protein from the PM of tobacco cells. Proteins that cross-reacted with antibodies to the 58- and 72-kilodalton subunits of the tonoplast ATPase of red beet storage tissue were greatly enriched in the TG fraction. The results with immunoblots and enzyme assays indicated that there was little cross-contamination between the tonoplast and PM vesicles. The molecular weights and isoelectric points of the PM ATPase and the tonoplast ATPase subunits were also determined using immunoblots of two-dimensional gels of the PM and TG proteins.     

Assessment of glycinebetaine and proline compartmentation by analysis of isolated beet vacuoles

Vacuoles isolated from storage root tissue of red beet (Beta vulgaris L.) do not leak significant quantities of betanin, sucrose, Na⁺ or K⁺ during isolation. This indicates that analysis of vacuoles in vitro gives meanigful information about the compartmentation of solutes in vivo. Preparations of vacouoles were used to determine the distribution of glycinebetaine and proline between vacuole and cytoplasm in beet cells. Both compounds were detected in preparations of isolated beet vacuoles. In the case of glycinebetaine it was shown that this solute was associated with the vacuoles, not with the small number of other organelles which contaminated the preparations. The vacuolar pool accounted for 26 to 84% of the total tissue glycinebetaine and 17 to 57% of the proline. Concentrations of these compounds in vacuole and cytoplasm were calculated and were always higher in the cytoplasm than in the vacuole. The concentration gradient across the tonoplast varied considerably. The significance of these results is discussed in relation to the hypothesis that glycinebetaine and proline function as benign cytoplasmic osmotica.Abbreviations A₅₃₇ absorbance at 537 nm - MES 2-(N-morpholino)-ethanesulphonic acid - Na₂EDTA ethylenediaminetetraacetic acid, disodium salt - SDS sodium dodecyl sulphate - Tris tris(hydroxymethyl)methylamine     

The role of the vacuole in the accumulation and mobilization of sucrose

The contribution that isolated vacuoles have made to understanding sucrose storage and mobilization is reviewed briefly, with particular reference to the storage root of red beet (Beta vulgaris L.). Work with isolated vacuoles has shown that in this tissue sucrose is confined to the vacuole and some progress has been made in elucidating the possible mechanism of sucrose transport into the vacuole. The evidence that this is a H⁺: sucrose antiport, dependent on the activity of a proton-translocating ATPase is examined. It is concluded that while there is some evidence for the presence of a proton pump, a link between this and sucrose uptake has still to be established. Using isolated vacuoles it has been demonstrated that during mobilization of sucrose, hydrolysis occurs within the vacuole but the mechanism of unloading of hexoses from the vacuole remains to be elucidated.     

Acid invertase (sucrose hydrolysis) is not required for sucrose mobilization from the vacuole

The possible involvement of acid invertase (sucrose hydrolysis) as a prerequisite for sucrose mobilization from the vacuole of storage cells was investigated. Sugarcane ( Saccharum officinarum ) stalks, carrot ( Daucus carota ) roots and red beet ( Beta vulgaris ) hypocotyls were planted under greenhouse conditions and allowed to resume growth. The plants, however, were not permitted to become photosynthetically autotrophic by removing the new expanded leaves. Sucrose levels declined significantly in all three tissues without the development of acid invertase (EC 3.2.1.26) during the 21‐day experimental period. Acid invertase and thus sucrose hydrolysis within the vacuole was, therefore, not required for sucrose mobilization.     

Proton Transport in Plasma Membrane and Tonoplast Vesicles from Red Beet (Beta vulgaris L.) Storage Tissue : A Comparative Study of Ion Effects on DeltapH and DeltaPsi

The proton transport properties of plasma membrane and tonoplast vesicles isolated from red beet (Beta vulgaris L.) storage tissue were examined and compared. Membrane vesicles isolated with 250 millimolar KCl in the homogenization media and recovered at low density following sucrose density gradient centrifugation displayed characteristics of proton transport (nitrate inhibition, no inhibition by orthovanadate, pH optimum of 7.75, pyrophosphate-driven proton transport) which were consistent with a tonoplast origin. When the KCl in the homogenization medium was replaced by 250 millimolar KI, sealed membrane vesicles were recovered at higher densities in sucrose gradients and displayed properties (orthovanadate sensitivity, no inhibition by nitrate, pH optimum of 6.5) consistent with a plasma membrane origin. A comparison of anion effects (potassium salts) upon ΔpH and ΔΨ revealed a direct correspondence between the relative ability of anions to stimulate proton transport and reduce ΔΨ. For tonoplast vesicles, the relative order for this effect was KI > KBr ≥ KCl > KClO₃ > K₂SO₄ while for plasma membrane vesicles, a different order KI > KNO₃ ≥ KBr ≥ KClO₃ > KCl > K₂SO₄ was observed. Proton transport in plasma membrane and tonoplast vesicles was inhibited by fluoride; however, plasma membrane vesicles appeared to be more sensitive to this anion. In order to correlate anion effects in the two vesicle fractions with anion transport, the kinetics of anion stimulation of steady-state pH gradients established in the absence of monovalent ions was examined. Anions were added as potassium salts and the total potassium concentration (100 millimolar) was maintained through the addition of K⁺/Mes. For plasma membrane vesicles, chlorate and nitrate displayed saturation kinetics while chloride displayed stimulation of proton transport which followed a linear profile. For tonoplast vesicles, the kinetics of chloride stimulation of proton transport displayed a saturable component. The results of this study indicate differences in proton transport properties of these two vesicle types and provide information on conditions where proton transport in the two fractions can be optimized.     

Non-invasive microscopy of tip-growing root hairs as a tool for study of dynamic and cytoskeleton-based vesicle trafficking

The techniques of live cell imaging by electronic light microscopy and confocal microscopy were used to analyse the cytoarchitecture, organelle dynamics and membrane trafficking in living root hairs of Arabidopsis thaliana and Medicago sativa. We focused on the motility of vesicles in the tip of growing root hairs, the internalisation of plasma membrane by endocytosis and the fate of endocytic compartments. Vesicles as well as their trafficking to and contact with the plasma membrane were visualised in the tip of root hairs. We showed rapid endocytosis using a pulse treatment with lipophillic FM dyes in growing root hairs. Endocytosis was active at the very tip and labelled endocytic membranes progressed further down the endocytic network through dynamic compartments merging with the vacuole by their fusion with highly dynamic tonoplast.     

Alkali Cation/Sucrose Co-transport in the Root Sink of Sugar Beet

The mechanism of sucrose transport into the vacuole of root parenchyma cells of sugar beet was investigated using discs of intact tissue. Active sucrose uptake was evident only at the tonoplast. Sucrose caused a transient 8.3 millivolts depolarization of the membrane potential, suggesting an ion co-transport mechanism. Sucrose also stimulated net proton efflux. Active (net) uptake of sucrose was strongly affected by factors that influence the alkali cation and proton gradients across biological membranes. Alkali cations (Na⁺ and K⁺) at 95 millimolar activity stimulated active uptake of sucrose 2.1- to 4-fold, whereas membrane-permeating anions inhibited active sucrose uptake. The pH optima for uptake was between 6.5 and 7.0, pH values slightly higher than those of the vacuole. The ionophores valinomycin, gramicidin D, and carbonyl cyanide m-chlorophenylhydrazone at 10 micromolar concentrations strongly inhibited active sucrose uptake. These data are consistent with the hypothesis that an alkali cation influx/proton efflux reaction is coupled to the active uptake of sucrose into the vacuole of parenchyma cells in the root sink of sugar beets.     

Isolation of tonoplast vesicles from tobacco protoplasts

Vacuoles were isolated from protoplasts of Nicotiana glutinosa by the method of Mettler and Leonard (Plant Physiol 1979 64: 1114-1120) with minor modifications so that the number of intact protoplasts contaminating the vacuole preparation was reduced to less than 1% (by number). Isopycnic centrifugation of a [³H]choline-labeled, sonicated vacuole preparation on linear 5 to 40% sucrose gradients indicated that tonoplast vesicles equilibrated at a density of about 1.12 grams per cubic centimeter. When tonoplast vesicles were isolated on discontinuous sucrose density gradients substrate specific ATPase activity was not found to be associated with this membrane fraction. These results are discussed in terms of the energetics of ion transport through the tonoplast membrane.     

ENDOCYTOSIS OF LANTHANUM NITRATE IN THE ORGANIC ACID-SECRETING TRICHOMES OF CHICKPEA (CICER ARIETINUM L.)

The organic acid-secreting trichomes of chickpea (Cicer arietinum L.) were exposed to 2.5 mm lanthanum nitrate for 24 hr, and this concentration did not inhibit trichome secretion compared with that of controls. We subsequently used this nontoxic concentration of lanthanum to examine endocytosis. In the stalk cells of these secretory trichomes, exogenously applied lanthanum nitrate was present in cell walls and vacuoles, as well as within both invaginations in the plasma membrane and vesicles in the peripheral cytoplasm between the plasma membrane and the tonoplast. In the head cells, lanthanum nitrate was present in cell walls and in vesicles that form a layer in the cytoplasm around the edge of the head cells, but was not present in vacuoles. We propose that fluid phase endocytosis targeted to the vacuole takes place in the stalk cells and that endocytosis occurs in the head cells to remove excess plasma membrane after the fusion of secretory vesicles with the plasma membrane. This is the first demonstration of endocytosis in secretory trichomes.