Plasmatubules: fact or artefact?

Plasmatubules are tubular evaginations of the plasmalemma associated with sites where high solute flux occurs between apoplast and symplast. Plasmatubules of the scutellar epithelial cells of germinating barley (Hordeum vulgare L.) have been examined following a variety of fixation methods. Of the aqueous fixations, primary aldehyde fixation with osmium post-fixation and osmium as the primary fixative gave comparable images, whilst potassium permanganate resulted in some distortion of the tissue in general including dilation of the tubular evaginations of the plasmalemma. Freeze-fixation and substitution with acetone and acetone-osmium gave images of the plasmalemma comparable to those obtained by the aqueous aldehyde and osmium methods. The similarity of structure with aldehyde or osmium and freezing as the primary fixation is taken to indicate that plasmatubules are real and not artefacts resulting from the fixation procedure.     

Plasmatubules: an alternative to transfer cells?

Tubular evaginations of the plasmalemma of the scutellar epithelial cells of barley are described. The evaginations are similar to those present at other sites where solute flux occurs for a limited period only and wall development of the transfer-cell form has not occured. Differential uptake of the fluorescent dyes fluorescein, which moves into the symplast, and 8-anilino-1-naphthalene sulphonic acid, which remains in the apoplast only, indicates that the scutellar epithelial cells contain the boundary between the apoplast and symplast. We suggest that i) the plasmalemma evaginations, which have a specific form and localisation, may be referred to as plasmatubules rather than by the general term plasmalemmasome, and that ii) the plasmatubules may act in membrane amplification in a short-term structural modification which is an alternative to transfer cells.Abbreviation ANS 8-anilino-1-naphthalene sulphonic acid     

Plasmatubules – real modifications of the plasmalemma

Plasmatubules are specific (approximately 20 nm diameter) evaginations of the plasmalemma, found at sites where high solute flux from apoplast to symplast is known, or inferred, to occur for short periods. First described in the distal, endosperm, end of barley scutellar epithelial cells, their structure has subsequently been confirmed using a range of both aqueous and non-aqueous fixation techniques. Plasmatubules have now been described in a range of tissues and species, and examination of published micrographs indicates that this range could be extended further.     

PLASMODESMATAL FREQUENCY AND OTHER STRUCTURAL ASPECTS OF ASSIMILATE COLLECTION AND PHLOEM LOADING IN LEAVES OF SONCHUS OLERACEUS (ASTERACEAE), A SPECIES WITH MINOR VEIN TRANSFER CELLS

Leaves of Sonchus oleraceus (Asteraceae) were examined with the electron microscope to determine plasmodesmatal frequencies and other structural features relating to the collection of photoassimilate and its subsequent loading into minor veins. Few plasmodesmata occur between mesophyll cells, which contain chloroplasts that are sometimes connected to both the plasmalemma and the tonoplast by membranous tubules. The minor veins consist of tracheary elements, sieve-tube members, vascular parenchyma cells, and companion cells. The latter two cell types are transfer cells, with some of the fingerlike wall ingrowths in companion cells being traversed lengthwise by plasmodesmata. The frequencies of plasmodesmata at the mesophyllbundle sheath boundary and within are higher at some interfaces than at corresponding interfaces in nine other species, including some that previously had been characterized as loading assimilate via the symplast. It is thus premature to designate all species containing transfer cells in their minor veins as loading assimilate only via the apoplast.     

<Emphasis Type="Italic">Amborella trichopoda</Emphasis>, plasmodesmata,and the evolution of phloem loading

Phloem loading is the process by which photoassimilates synthesized in the mesophyll cells of leaves enter the sieve elements and companion cells of minor veins in preparation for long distance transport to sink organs. Three loading strategies have been described: active loading from the apoplast, passive loading via the symplast, and passive symplastic transfer followed by polymer trapping of raffinose and stachyose. We studied phloem loading in Amborella trichopoda, a premontane shrub that may be sister to all other flowering plants. The minor veins of A. trichopoda contain intermediary cells, indicative of the polymer trap mechanism, forming an arc on the abaxial side and subtending a cluster of ordinary companion cells in the interior of the veins. Intermediary cells are linked to bundle sheath cells by highly abundant plasmodesmata whereas ordinary companion cells have few plasmodesmata, characteristic of phloem that loads from the apoplast. Intermediary cells, ordinary companion cells, and sieve elements form symplastically connected complexes. Leaves provided with ¹⁴CO₂ translocate radiolabeled sucrose, raffinose, and stachyose. Therefore, structural and physiological evidence suggests that both apoplastic and polymer trapping mechanisms of phloem loading operate in A. trichopoda. The evolution of phloem loading strategies is complex and may be difficult to resolve.     

Determination of subcellular concentrations of soluble carbohydrates in rose petals during opening by nonaqueous fractionation method combined with infiltration–centrifugation method

Petal growth associated with flower opening depends on cell expansion. To understand the role of soluble carbohydrates in petal cell expansion during flower opening, changes in soluble carbohydrate concentrations in vacuole, cytoplasm and apoplast of petal cells during flower opening in rose (Rosa hybrida L.) were investigated. We determined the subcellular distribution of soluble carbohydrates by combining nonaqueous fractionation method and infiltration–centrifugation method. During petal growth, fructose and glucose rapidly accumulated in the vacuole, reaching a maximum when petals almost reflected. Transmission electron microscopy showed that the volume of vacuole and air space drastically increased with petal growth. Carbohydrate concentration was calculated for each compartment of the petal cells and in petals that almost reflected, glucose and fructose concentrations increased to higher than 100 mM in the vacuole. Osmotic pressure increased in apoplast and symplast during flower opening, and this increase was mainly attributed to increases in fructose and glucose concentrations. No large difference in osmotic pressure due to soluble carbohydrates was observed between the apoplast and symplast before flower opening, but total osmotic pressure was much higher in the symplast than in the apoplast, a difference that was partially attributed to inorganic ions. An increase in osmotic pressure due to the continued accumulation of glucose and fructose in the symplast may facilitate water influx into cells, contributing to cell expansion associated with flower opening under conditions where osmotic pressure is higher in the symplast than in the apoplast.     

Regulation of plant elongation growth by surface and xylem proton pumps

The roles of plasmalemma electrogenic proton pumps in elongation growth of plant stems are discussed on the basis of growth-electrophysiological studies on hypocotyl segments ofVigna unguiculata. Plant stems usually have two spatially separated electrogenic proton pumps: the surface proton pump which is located on the surface membrane of the symplast and the xylem proton pump, on the cell membrane of the symplast/xylem apoplast boundary. The surface proton pump excretes protons into the surface cell wall layer and causes the loosening of the cell wall. The xylem proton pump excretes protons into the xylem apoplast and drives the uptake of solute and water into the symplastvia secondary and/or tertiary active mechanisms: the proton cotransport system and the apoplast canal system. Both the surface and the xylem proton pumps are active during elongation growth because both the yielding of cell wall loosening and the uptake of water are necessary for continued elongation growth.     

Efflux of sucrose from minor veins of tobacco leaves

Mature leaves import limited amounts of nutrient when darkened for prolonged periods. We tested the hypothesis that import is restricted by the apoplast-phloem loading mechanism, ie., as sucrose exits the phloem of minor veins it is retrieved by the same tissue, thus depriving the mesophyll of nutrient. When single, attached, mature leaves of tobacco (Nicotiana tabacum L.) plants were darkened, starch disappeared from the mesophyll cells, indicating that the supply of solute to the mesophyll was limited. Starch was synthesized in mesophyll cells of darkened tissue when sucrose was applied to the apoplast at 0.1–0.3 mM concentration. Efflux from minor veins was studied by incubating leaf discs on [¹⁴C]sucrose to load the minor veins and then measuring subsequent ¹⁴C release. Efflux was rapid for the first hour and continued at a gradually decreasing rate for over 13 h. Net efflux increased when loading was inhibited by p-chloromercuribenzene-sulfonic acid, anoxia, isotope-trapping, or reduction of the pH gradient. Neither light nor potassium had a significant effect on the rate of labeled sucrose release. The site of labeled sucrose release was investigated by measuring efflux from discs in which sucrose had previously been loaded preferentially by either the minor veins or mesophyll cells. Efflux occurred primarily from minor veins.Abbreviations Mes 2(N-morpholino)ethanesulfonic acid - Mops 3(N-morpholino)propanesulfonic acid - PCMBS p-chloromercuribenzenesulfonic acid - SE-CC sieve element-companion cell complex     

The apoplastic continuum,nutrient absorption and plasmatubules in the dwarf mistletoeKorthalsella lindsayi (Viscaceae)

Summary The transfer of nutrients between host and parasite in mistletoes has generally been considered to occur via the xylem to xylem contacts at the host-parasite interface in the haustorial organ of attachment. A few workers, however, have recently begun to question this assumption and have suggested an alternative pathway of transport involving the intervening parenchyma cells which are often abundant in the parasite at the interface. But no morphological experimental evidence has yet been forthcoming in support of an apoplastic continuum across this interface between parasite and host.Our observations on the dwarf mistletoeKorthalsella lindsayi first indicate an absence of plasmodesmata at the interface, with the conclusion that symplastic transport between the two plants is not involved. However, application of apoplastic markers, such as Calcofluor white and lanthanum and uranyl ions, to the stem of the host results in the transfer of these tracers across the interface and into the tissues of the parasite. This demonstrates the existence of an apoplastic continuum between the two plants, and a pathway that is probably used in the normal transfer of water and other nutrients from host to parasite.From the apoplastic continuum provided by the walls of the haustorial parenchyma tissue, nutrients are transferred to the symplast for eventual distribution to other parts of the plant. Evidence for the active uptake of substances from the apoplast by the protoplasts of the parenchyma cells is shown by the convoluted appearance of the plasmalemma and its differentiation often into plasmatubules.     

Water Flow in Beta vulgaris Storage Tissue

The relative magnitudes of the hydraulic resistances, water capacities, and water potential equilibration time constants for the single cell, for the apoplast, and for the symplast in higher plant tissue are assessed. Swelling of beetroot (Beta vulgaris, var. `Detroit Red') storage tissue sections in pure water is measured using a displacement transducer. This method of measurement avoids the difficulty of solute diffusion in the apoplast. Theoretical analysis of the experimental results shows that the main path of water flow into the tissue is the apoplast rather than the symplast, that the main resistance to water flow into the cells is usually the cell membrane rather than the apoplast, but that in some cases the apoplast resistance and water capacity can contribute significantly to the water potential equilibration time constant of the tissue.     

The intermediary cell: Minor-vein anatomy and raffinose oligosaccharide synthesis in the Scrophulariaceae

Minor-vein anatomy, sugar content, sugar synthesis, and translocation were studied in mature leaves of nine members of the Scrophulariaceae to determine if there is a correlation between companion-cell type and class of sugar translocated. Three types of companion cell were found: intermediary cells with extensive plasmodesmatal connections to the bundle sheath; transfer cells with wall ingrowths and few plasmodesmata; and ordinary companion cells with few plasmodesmata and no wall ingrowths. Alonsoa warscewiczii Regal., Verbascum chaixi Vill., and Mimulus cardinalis Dougl. ex. Benth. have intermediary cells and ordinary companion cells in the minor veins. These plants synthesize large amounts of raffinose and stachyose as well as sucrose. Nemesia strumosa Benth., and Rhodochiton atrosanguineum Zucc. have both intermediary cells and transfer cells and make proportionately less raffinose oligosaccharide than the species above. In N. strumosa, a single sieve element may abut both an intermediary cell and a transfer cell. The minor veins of Asarina scandens (Cav.) Penn. have transfer cells and what appear to be modified intermediary cells that have fewer plasmodesmata than other species, and occasional wall ingrowths. Asarina scandens synthesizes little raffinose or stachyose. Cymbalaria muralis P. Gaertn et al. and Linaria maroccana Hook.f. have only transfer cells and Digitalis grandiflora Mill. has only ordinary companion cells; these species make a trace of galactinol and raffinose, but no stachyose. Translocation experiments indicate that there is long-distance movement of raffinose oligosaccharide in these plants, even when it is synthesized in very small quantities in the leaves. We conclude that intermediary cells are as distinct a cell type as the transfer cell. In contrast to transfer cells, which are specialized for uptake of solute from the apoplast, intermediary cells are specialized for symplastic transfer of photoassimilate from the mesophyll and for synthesis of raffinose oligosaccharide. This supports our contention that raffinose oligosaccharide synthesis and symplastic phloem loading are mechanistically linked (Turgeon and Gowan 1990, Plant Physiol. 94, 1244–1249). Minor-vein anatomy and sugar synthesis may be useful characters in determining the phylogenetic relationships of plants in this family.We thank Andrea Wolfe and Wayne Elisens for helpful discussions on the taxonomy of the Scrophulariaceae. This research was supported by National Science Foundation grant DCB-9104159, U.S. Department of Agriculture Competetive Grant 92-37306-7819, and Hatch funds.     

Movement of Lucifer Yellow CH in potato tuber storage tissues: A comparison of symplastic and apoplastic transport

The fluorescent dye Lucifer Yellow CH (LYCH) was introduced directly into the symplast of potato (Solanum tuberosum L.) tuber storage parenchyma by microinjection and also into the apoplast through cuts made in the stolon cortex. Microinjected LYCH moved away rapidly from a single storage cell and spread radially via the symplast. When the microinjected tissue was subsequently fixed in glutaraldehyde and sectioned the dye was seen clearly to be localised in the cytoplasm but not in the vacuole. In comparison, when LYCH was introduced into cuts made in the stolon cortex the dye entered the tuber by the xylem and subsequently spread apoplastically. No movement of dye was observed in the phloem. In glutaraldehyde-fixed tissues, in which LYCH was introduced to the apoplast, the dye was found within xylem vessels, in the cell walls and in intercellular spaces. Wall regions, possibly associated with plasmodesmata, became stained by the dye as it moved through the apoplast. Three hours after introduction of the dye to the stolon, intense deposits of LYCH were found in the vacuoles of all cells in the tuber, many aligned along the tonoplast. Differentiating vascular parenchyma elements contained large amounts of dye within enlarging vacuoles. However, with the exception of plasmolysed and-or damaged cells, LYCH was absent from the cytoplasm following its introduction to the plasmalemma it is suggested that the most likely pathway from the cell wall to the vacuole was by endocytosis, the dye being transported across the cytoplasm in membrane-bound vesicles. Clathrin-coated vesicles were abundant in the storage cells, providing a possible endocytotic pathway for dye movement. The significance of these observations is discussed in relation to the movement of LYCH in plant tissues and to the movement of solutes within and between storage cells of the tuber.Abbreviation LYCH Lucifer Yellow CH     

The Cellular Pathway of Short-distance Transfer of Photosynthates and Potassium in the Elongating Stem of Phaseolus vulgaris L. A Structural Assessment

The potential cellular pathway of radial transfer of photosynthateand potassium delivered in the phloem to the elongation zone(apical 0.5–2.5 cm) of internode 2 ofPhaseolus vulgarisL. seedlings was elucidated. This was achieved using ultrastructuralobservations of the cell types that constitute the radial pathwayand estimates of potential sucrose and potassium fluxes throughthe cross-sectional area of interconnecting plasmodesmata andacross the plasma membrane surface areas of selected cell types.The investigation relied on predicting the relative roles ofthe mature and developing sieve elements as conduits for theaxial delivery of solutes to the elongation zone. In turn, thesepredictions led to formulation of two transport models whichwere subsequently evaluated. It was found that unloading ofsucrose and potassium from the protophloem sieve elements cannotbe through the symplast due to the absence of plasmodesmata.On the other hand, mature metaphloem sieve element-companioncell complexes have the potential capacity to unload eitherthrough the stem symplast or apoplast. The potential symplasticroute is proposed to be via the companion cells to the adjacentlarge phloem parenchyma cells. Continued radial transfer couldoccur either by exchange to the stem apoplast from the largephloem parenchyma cells or continue in the symplast to the groundtissues. It was further predicted that sucrose utilized forthe development of the procambial/small phloem parenchyma cellscould be delivered axially by them and not by the mature sieveelements. Phaseolus vulgaris ; apoplast; elongating stem; photosynthates; potassium; transport; symplast     

The cellular pathway of photosynthate transfer in the developing wheat grain. I. Delineation of a potential transfer pathway using fluorescent dyes

A potential cellular pathway for photosynthate transfer between the crease phloem and the starchy endosperm of the developing wheat grain has been delineated using fluorescent dyes. Membrane permeable and impermeable dyes have been introduced into the grain through the crease phloem, the endosperm cavity or the dorsal surface of the starchy endosperm. The movement of the symplastic tracer 5-(6)-6-carboxyfluorescein (CF) derived from 5-(6)-6-carboxyfluorescein diacetate (CFDA), from either direction between the crease phloem and the endosperm cavity, indicated that the symplastic pathway was operative from the crease phloem to the nucellar projection. Furthermore, the inward movement of apoplastic tracer trisodium, 3-hydroxy-5,8,10-pyrentrisulphonate (PTS) from the endosperm cavity and that of CF following plasmolysis showed that there was a high resistance to solute transfer within the apoplast of the pigment strand. All dyes entered the modified aleurone and adjacent sub-aleurone bordering the endosperm cavity. Subsequent movement of the symplastic tracers CF and sulphorhodamine G (SRG) into and through the endosperm was rapid. However, the movement of apoplastic tracers PTS and Calcofluor White (CFW) was relatively slow and with tissue plasmolysis, CF was confined to the cytoplasm of the modified aleurone and subaleurone cells. Together, these results demonstrate that there is a high resistance to solute movement within the apoplast of the cells bordering the endosperm cavity. We propose that photosynthate transfer is via the symplast to the nucellar projection where membrane exchange to the endosperm cavity occurs. Uptake from the cavity is by the modified aleurone and small endosperm cells prior to transfer through the symplast to and through the starchy endosperm.     

What Is Phloem Unloading?

Several studies of phloem unloading have failed to distinguish between transport events occurring at the sieve element/companion cell boundary and subsequent short-distance transport through parenchyma cells. Indirect evidence has been obtained for symplastic unloading in storage and utilization sinks. In other sinks transfer to the apoplast may occur, but not necessarily at the sieve element/companion cell complex, and the evidence for apoplastic phloem unloading is equivocal, as is the role of apoplastic acid invertase in this process. The ability of several types of sink cells to accumulate sugars from the apoplast is discussed in the conflicting light of functional symplastic continuity between sink cells. Attention is drawn to the complexity of the postunloading pathway in many sinks and the difficulty of determining the exact sites of symplast/apoplast solute exchange. Potential future areas for study in the field are highlighted.     

The cellular pathway of photosynthate transfer in the developing wheat grain. II. A structural analysis and histochemical studies of the pathway from the crease phloem to the endosperm cavity

In the developing wheat grain, photosynthate is transferred longitudinally along the crease phloem and then laterally into the endosperm cavity through the crease vascular parenchyma, pigment strand and nucellar projection. In order to clarify this cellular pathway of photosynthate unloading, and hence the controlling mechanism of grain filling, the potential for symplastic and apoplastic transfer was examined through structural and histochemical studies on these tissue types. It was found that cells in the crease region from the phloem to the nucellar projection are interconnected by numerous plasmodesmata and have dense cytoplasm with abundant mitochondria. Histochemical studies confirmed that, at the stage of grain development studied, an apoplastic barrier exists in the cell walls of the pigment strand. This barrier is composed of lignin, phenolics and suberin. The potential capacity for symplastic transfer, determined by measuring plasmodesmatal frequencies and computing potential sucrose fluxes through these plasmodesmata, indicated that there is sufficient plasmodesmatal cross-sectional area to support symplastic unloading of photosynthate at the rate required for normal grain growth. The potential capacity for membrane transport of sucrose to the apoplast was assessed by measuring plasma membrane surface areas of the various cell types and computing potential plasma membrane fluxes of sucrose. These fluxes indicated that the combined plasma membrane surface areas of the sieve element–companion cell (se–cc) complexes, vascular parenchyma and pigment strand are not sufficient to allow sucrose transfer to the apoplast at the observed rates. In contrast, the wall ingrowths of the transfer cells in the nucellar projection amplify the membrane surface area up to 22-fold, supporting the observed rates of sucrose transfer into the endosperm cavity. We conclude that photosynthate moves via the symplast from the se–cc complexes to the nucellar projection transfer cells, from where it is transferred across the plasma membrane into the endosperm cavity. The apoplastic barrier in the pigment strand is considered to restrict solute movement to the symplast and block apoplastic solute exchange between maternal and embryonic tissues. The implications of this cellular pathway in relation to the control of photosynthate transfer in the developing grain are discussed.     

Symplast domains in extrastelar tissues of Egeria densa Planch.

A set of hydrophilic fluorescent dyes of known molecular weight has been used to determine the molecular exclusion limit and the extent of apical, epidermal and cortical symplasts in the root, stem and leaf of Egeria densa. These dyes are unable to pass the plasmalemma, so that any cell-to-cell movement of injected dye must occur via the symplast. The shoot-apex symplast has a high molecular exclusion limit, excluding dyes with a molecular weight of 749 dalton (fluorescein hexaglycine) and greater but allowing dyes of up to 665 dalton (fluorescein diglutamic acid) to pass. The leaf epidermal symplast is similar to that in the apex: fluorescein pentaglycine (674 dalton) moves to a limited extent, but fluorescein hexaglycine is immobile. Stem and root epidermal cells have a lower molecular exclusion limit, only the dye 6-carboxyfluorescein (376 dalton) is able to move from cell-to-cell. Cortical and epidermal tissues in both the stem and the root have similar symplast permeabilities. However, a barrier to dye (6-carboxyfluorescein) movement is found between the epidermis and the cortex in both organs. Barriers are also found at the nodes between expanded internodes. The stem barriers are not found in the unexpanded nodes near the shoot tip; apparently they are formed early during internode expansion. In the root tip, a barrier to the movement of dye is found between the root cap and the remainder of the root. Plasmodesmata are found linking all cell types studied, even cells where barriers to dye movement occur. Thus, the plant, far from being one uniform symplast, consists of a large number of symplast domains, which may or may not differ in molecular exclusion limit.Abbreviations F fluorescein isothiocyanate isomer I - Glu l-glutamic acid - (Glu)₂ l-glutamylglutamic acid - (Gly)₅ l-pentaglycine - (Gly)₆ l-hexaglycine     

Pathway of Photosynthate Transfer in the Developing Seed of Vicia faba L: A Structural Assessment of the Role of Transfer Cells in Unloading from the Seed Coat

Photosynthate movement within the coat of the developing seedof Vicia faba occurs radially inward from the restricted vascularsystem and laterally through the non-vascularized region ofthe seed coat prior to exchange to the seed apoplast. Thin-walledparenchyma/transfer cells line the entire inner surface of theseed coat and thus are located at the terminus of the photosynthatetransfer pathway. The principal cellular route of transfer withinthe seed coat and the role of the thin-walled parenchyma/transfercells in membrane exchange to the seed apoplast has been investigated.Sucrose fluxes, computed from estimates of the plasma membranesurface areas of the cell types of the pathway, the plasmodesmatalcross-sectional areas interconnecting contiguous cells and theobserved rate of sucrose delivery to the embryo indicate thatsieve element unloading and subsequent transfer to the thin-walledparenchyma/transfer cells is through the symplast. For the cellsof the ground tissue, plasmodesmatal density is consistentlyhigher on their anticlinal walls. This observation supportsthe reported pattern of lateral transfer through these tissuesin the non-vascular regions of the seed coat. Wall ingrowthsare initiated sequentially in the thin-walled parenchyma cellsto maintain 1–3 rows of thin-walled parenchyma/transfercells. The development of these wall ingrowths results in a58% increase in the plasma membrane surface area of these cellsand provides them with the capacity to act as the principalcellular site for membrane exchange of sucrose to the seed apoplast.This cellular route of symplastic transfer from the sieve elementsto the ground tissues where membrane exchange to the seed apoplastoccurs is consistent with that reported for Phaseolus vulgaris Key words: Cellular pathway, photosynthate transfer, transfer cell, Vicia seed coat     

Studies on the leaf of Amaranthus retroflexus (Amaranthaceae): ultrastructure,plasmodesmatal frequency,and solute concentration in relation to phloem loading

Both the mesophyll and bundle-sheath cells associated with the minor veins in the leaf of Amaranthus retroflexus L. contain abundant tubular endoplasmic reticulum, which is continuous between the two cell types via numerous plasmodesmata in their common walls. In bundle-sheath cells, the tubular endoplasmic reticulum forms an extensive network that permeates the cytoplasm, and is closely associated, if not continuous, with the delimiting membranes of the chloroplasts, mitochondria, and microbodies. Both the number and frequency of plasmodesmata between various cell types decrease markedly from the bundle-sheath — vascular-parenchyma cell interface to the sicve-tube member — companion-cell interface. For plants taken directly from lighted growth chambers, a stronger mannitol solution (1.4 M) was required to plasmolyze the companion cells and sieve-tube members than that (0.6 M) necessary to plasmolyze the mesophyll, bundle-sheath, and vascular-parenchyma cells. Placing plants in the dark for 48 h reduced the solute concentration in all cell types. Judging from the frequency of plasmodesmata between the various cell types of the vascular bundles, and from the solute concentrations of the various cell types, it appears that assimilates are actively accumulated by the sieve-tube — companion-cell complex from the apoplast.     

The effect of lead on the cell cycle in the root meristem ofAllium cepa L.

Summary Allium cepa (L.) adventitious roots were treated with lead (2.5 mg of Pb²⁺ [from Pb(NO₃)₂] per dm³) for 30–72 h. The cell cycle was studied by pulse labeling with [³H]thymidine. Mitotic activity kinetics, occurrence of disturbed mitoses (c-mitoses), and level of DNA synthesis were examined. It was found that lead prolonged the cell cycle and that cells in two phases of the cycle, G₂ and S, differed in their sensitivity to lead. Cells in G₂ were more sensitive; lead lengthened their cycle by 216% and disturbed the course of cell division by causing c-mitoses. Cells in S phase were less sensitive. Their cell cycle was longer by 55%. They went through their G₂ phase without major disturbances, mitosis in these cells was normal. During treatment ofA. cepa with lead, its destructive effects on cells were exerted only during the first few hours (around 6 h) of incubation. That is when the inhibition of mitotic activity, numerous disturbances of cell division, a decline in the number of cells synthesizing DNA, and a lower level of DNA synthesis were observed. As the incubation continued, the above processes were found to return to normal. In the discussion, data are presented supporting the hypothesis that during the initial period of exposure ofA. cepa to lead, this metal enters both the root apoplast and symplast, exerting a destructive effect on cells, while later, lead penetrates only into the root apoplast, and in this way remains harmless to cells.