Tissue slices from living root caps as a model system in which to study cytodifferentiation of polar cells

Tissue slices of living root caps of cress (Lepidium sativum L.), two to three cell layers in thickness, were prepared by a microsurgical procedure. The viability, cellular structures and cytoplasmic movement of the cells were examined in the light microscope. Nuclei, amyloplasts, vacuoles and endoplasmic reticulum were identified and their positions confirmed after fixation and observation of the same cells in the electron microscope. The distribution of microtubules was shown by immunocytochemistry. During germination, microtubules appear first at the distal edges of the statocytes, while in mature statocytes a distal domain of criss-crossed microtubules could be distinguished from a proximal domain with transversally oriented microtubules. Microfilaments in young statocytes form a nuclear enclosure; in mature statocytes bundles of microfilaments fan out into the cell cortex. The transition from statocytes to secretion cells is accompanied by a more pronounced cortical network of microfilaments, while the nucleus-associated microfilaments remain visible. It is suggested that these microfilaments play a role in the positioning of the nucleus and the translocation of endoplasmic reticulum.Abbreviations ER endoplasmic reticulum - MF microfilament - MT microtubule     

Gravitropic bending of cress roots without contact between amyloplasts and complexes of endoplasmic reticulum

The polar arrangement of cell organelles in Lepidium root statocytes is persistently converted to a physical stratification during lateral centrifugation (the centrifugal force acts perpendicular to the root long axis) or by apically directed centrifugation combined with cytochalasin-treatment. Lateral centrifugation (10 min, 60 min at 10\g or 50\g) causes displacement of amylplasts to the centrifugal anticlinal cell wall and shifting of the endoplasmic reticulum (ER) complex to the centripetal distal cell edge. After 60 min of lateral centrifugation at 10\g or 50\g all roots show a clear gravitropic curvature. The average angle of curvature is about 40° and corresponds to that of roots stimulated gravitropically in the horizontal position at 1\g in spite of the fact that the gravistimulus is 10-or 50-fold higher. Apically directed centrifugation combined with cytochalasin B (25 g\ml^-1) or cytochalasin D (2.5 g\ml^-1) incubation yields statocytes with the amyloplasts sedimented close to the centrifugal periclinal cell wall and ER cisternae accumulated at the proximal cell pole. Gravitropic stimulation for 30 min in the horizontal position at 1\g and additional 3 h rotation on a clinostat result in gravicurvature of cytochalasin B-treated centrifuged (1 h at 50\g) roots, but because of retarded root growth the angle of curvature is lower than in control roots. Cytochalasin D-treatment during centrifugation (20 min at 50\g) does not affect either root growth or gravicurvature during 3 h horizontal exposure to 1\g relative to untreated roots. As lateral centrifugation enables only short-term contact between the amyloplasts and the distal ER complex at the onset of centrifugation and apically directed centrifugation combined with cytochalasin-treatment even exclude any contact the integrity of the distal cell pole need not necessarily be a prerequisite for graviperception in Lepidium root statocytes.Abbreviations CB cytochalasin B - CD cytochalasin D - ER endoplasmic reticulum - g gravitational acceleration     

Hormone treatment of roots causes not only a reversible loss of starch but also of structural polarity in statocytes

Treatment of cress (Lepidium sativum L.) roots with phytohormones (4.3 x 10(-5) M gibberellic acid plus 4.3 x 10(-5) M kinetin, 30 h; T.H. Iversen, 1969, Physiol. Plant. 22, 1251-1262) caused not only complete destarching of amyloplasts but also destruction of the polar arrangement of cell organelles in statocytes. The nucleus was not positioned exclusively near the proximal cell pole as in the controls but was also found near the distal cell pole. The endoplasmic reticulum (ER) was no longer organized in parallel sheets at the distal cell pole but instead the ER-cisternae were randomly distributed. Additionally, the statocytes from hormone-treated roots contained a large central vacuole instead of numerous small ones as in the controls. The starch-free plastids had a reduced volume and an amoeboid shape. They did not sediment but were randomly distributed in the statocytes. The loss of structural polarity was accompanied by loss of graviresponsiveness although root growth still occurred. Twenty-two hours after removal of the hormones, structural polarity was restored and starch was resynthesized. The newly formed starch grains were smaller and more numerous per amyloplast compared to the controls. It is concluded that loss of gravisensitivity of roots after hormone treatment cannot be solely attributed to the loss of amyloplastic starch because there is a concomitant loss in the polar organisation of the statocyte.     

Cytodifferentiation of polar plant cells Use of anti-microtubular agents during the differentiation of statocytes from cress roots (Lepidium sativum L.)

The development of the structural polarity of statocytes from cress roots (Lepidium sativum L.) was studied in a time- and stage-dependent manner. Outgrowing radicles had statocytes with abundant lipid droplets, sparsely developed endoplasmic reticulum (ER) and nuclei located at the proximal cell poles. During differentiation, coincidentally the lipid droplets disappeared, while rough ER increased in length. The ER was translocated into the distal cell pole to establish a complex of stacked ER. Microtubules occurred first at the distal cell edges. As a second step, ER was produced in the vicinity of the nucleus and was also translocated distally. By application of the antimicrotubular agents heavy water (90%), colchicine (10^-4 mol·l^-1) and triethyl lead chloride (20 mol·l^-1), the involvement of microtubules in these events was studied. Triethyl lead chloride led to a complete cessation of differentiation; root-cap cells remained at a stage without polar arrangement of the ER. Colchicine affected the development of structural polarity slightly, as shown by a higher density of cortical ER cisternae. Heavy water inhibited the translocation of ER almost completely and yielded ER located also in the cell center. All anti-microtubular agents inhibited cell division and the differentiation of the distal cell layer of the dermatocalyptrogen into statocytes. It is hypothesized that microtubules serve as anchoring sites for microfilaments, which actually mediate the translocation of the ER. Hence, an intact system of microtubules and microfilaments is necessary for the expression of structural polarity.Abbreviations DC dermatocalyptrogen - ER endoplasmic reticulum - M meristem cell layer - MT microtubule - pI prospective story I - TrEl triethyl lead chloride     

Microtubules in statocytes from roots of cress (Lepidium sativum L.)

Summary Statocytes in root caps ofLepidium sativum L. were examined by means of ultrathin serial sections to evaluate the amount and distribution of cortical microtubules. The microtubules encircle the cell, oriented normal to the root length axis. In the distal cell edges, microtubules form a network, separating the distal complex of endoplasmic reticulum from the plasmalemma. Preprophase bands in meristem cells are observable rarely, structures which can be regarded as nucleating sites for microtubules are lacking. During ageing of the root cap cells, the number of microtubules increases in combination with a decrease of microtubule length. Development of the roots on a horizontal clinostat preserves a younger developmental stage of the microtubule system regarding amount and length of the individual microtubules. Evidence for an involvement of microtubules in graviperception is low, whereas their role in orienting cellulose microfibrils cannot be ruled out. Compression of the distal network of microtubules after centrifugation of the roots indicates that microtubules in statocytes ofLepidium sativum L. roots might function in stabilizing the distal complex of endoplasmic reticulum.     

Restitution of polarity in statocytes from centrifuged roots*

Abstract The structural polarity of statocytes from cress roots is changed by centrifugation. Upon low- dose centrifugation (3000 g min), the extent of stratification depends on statocyte position, i.e., central statocytes are affected more than lateral ones. Upon higher doses of centrifugation (60,000 and 360,000 g min), a uniform density gradient is established in all statocytes. If, after centrifugation, the roots are exposed to gravity again, the endoplasmic reticulum (ER) cisternae are relocated parallel to the periclinal cell walls within a few minutes; this relocation is independent of the direction of gravity in relation to the root axis, and independent of the previously applied centrifugation dose. This supports the notion that polarity is determined genetically. Cytochalasin B treatment, before and during centrifugation, totally inhibits the relocation of ER. After removing the drug by rinsing the roots, the statocytes restore cell polarity and relocate ER. These results indicate that relocation of ER cisternae may be mediated by microfilaments. When centrifuged roots are exposed to 1 g in the horizontal position, the latent period of gravitropism increases by 8–10 min relative to controls, regardless of the previously applied centrifugation doses. The kinetics of curvature are virtually identical. Since the increase in the latent period coincides with the time needed for most statocytes to restore the distal cell pole, it is evident that perception of gravity is correlated to the integrity of the distal cell pole.     

Effects of prolonged omnilateral gravistimulation on the ultrastructure of statocytes and on the graviresponse of roots

Statocytes of vertically growing roots of Lepidium sativum L. exhibit a strict polarity: The nucleus is positioned near the proximal periclinal cell wall, amyloplasts are sedimented on a complex of rough endoplasmic reticulum (ER) consisting of parallel cisternae near the distal periclinal cell wall.When 24 h old, vertically grown roots are rotated for an additional 20 h on a horizontal clinostat, this polarity is destroyed. Furthermore, the prolonged omnilateral stimulation leads to a damage of the statocytes, which in some cases ends in the self-destruction of the sensitive cells. The different components of the ultrastructural respones of the statocytes are: Displacement of the nucleus; changes in amount and distribution of the ER; loss of amyloplast starch; confluence of lipid droplets to large aggregates: a considerable increase of the lytic compartment. In addition, even anticlinal cell walls may be lysed up to small stumps. As all these effects are clearly restricted to the statocytes, only these cells are able to respond to the continuously changing direction of the gravity vector, thus perceiving gravity as such.After being exposed horizontally, the graviresponse of rotated roots is delayed as compared to the controls. About 20% of the rotated roots do not respond (curve) at all, but grow perpendicular in relation to the gravity vector. Perception of gravity is inevitably correlated with the polarity and the integrity of the statocytes.Abbreviation ER endoplasmic reticulum A preliminary report was presented at the Fall Meeting of the German Society for Cell Biology in Salzburg, Austria, September 1979 (Hensel and Sievers 1979)This paper represents part of a dissertation (D 5) of W. H.     

Cytochalasin B affects the structural polarity of statocytes from cress roots (Lepidium sativum L.)

Summary The effect of cytochalasin B (CB; 25 ·ml^–1 in 1% dimethylsulfoxide, DMSO) upon the structural polarity of statocytes in cress roots is demonstrated. If normal, vertically grown roots are incubated in CB, the structural polarity of the statocytes is altered according to the developmental stage of the root. Statocytes from young roots (13 or 17 hours, additionally 7 hours CB) are characterized by proximal ER cisternae and a sparsely developed distal ER-complex. Statocytes from older roots (24 hours, additionally 7 hours CB) still accumulate distal ER, as in control roots, but at the proximal cell pole in the vicinity of the nucleus additional ER is found. These effects are reversed by washing out the drug in DMSO. Growth of the roots under a continuous supply of CB yields statocytes with sedimented nuclei, proximal ER and almost no distal ER. Together with quantitative data from morphometric studies, a dynamic model of the expression of inherent cell polarity in structural polarity is proposed.Abbreviations CB cytochalasin B - DMSO dimethylsulfoxide - ER endoplasmic reticulum Preliminary results were presented at the joint Annual Meeting of the Belgian and German Society for Cell Biology, Bonn, 18–22 March 1985; Eur. J. Cell Biol. 36 (Suppl. 7), 1985, 25.Dedicated to Professor Dr. A.Betz on the occasion of his 65th birthday.     

Membrane-potential responses following gravistimulation in roots of Lepidium sativum L.

Membrane potentials were measured in lateral statocytes of vertically and nonvertically growing roots of Lepidium sativum L. using conventional glass-microelectrode techniques. Statocytes in vertically growing roots showed a stable resting potential of-118±5.9 mV without spontaneous fluctuations. Upon tilting the root 45° from the vertical, an electrical asymmetry was observed. Statocytes on the physically lower side of the root depolarized by approx. 25 mV. This depolarization occurred following a latent period of 8 s reaching a minimum (approx.-93 mV) after 170 s. This depolarization is the earliest event in graviperception ever recorded. After this depolarization, the cell repolarized within 60 s to a potential approx. 10 mV more positive than the original resting potential. Statocytes on the upper flank showed a slow hyperpolarization (t _1/2h=half time for hyperpolarization=168 s) reaching a final, stable potential at a level 10 mV more negative. These effects of gravistimulation were statenchyma-specific, since cells in the cortex and rhizodermis showed no similar effects. The gravi-electrical responses were observed in 25% of all roots tested. Roots which showed no gravi-electrical response had a reduced elongation growth, lacked gravity-induced bending and lacked the typical structural polarity in punctured statocytes. This observed transition from a symmetrical pattern of resting potential in the statenchyma to an asymmetrical pattern following gravistimulation supports the results observed with external current measurements (Behrens et al., Plant Physiol. 70, 1079–1083, 1982) and extends these results to the cellular level and to considerably improved temporal resolution. The asymmetry in the gravi-electrical response extends the graviperception model of Sievers and Volkmann (Planta 102, 160–172, 1972) which comprises an asymmetrical sedimentation of the amyloplasts on the distal endoplasmic reticulum of statocytes. This generates an intraorgan signal which then must be transmitted to the growth zone.Abbreviation ER endoplasmic reticulum Preliminary reports were presented at the 11^th International Conference on Plant Growth Substances, Aberystwyth, July 1982, and International Symposium, Membranes and Compartimentation in Regulation of Plant Functions, Toulouse, September 1983     

Dorsiventralität der Statocyten in plagiogeotropen Seitenwurzeln von Lepidium sativum L.

Summary The calyptra of plagiotropic lateral roots of Lepidium sativum L. is composed of three rows of cells. Movable amyloplates, possibly functioning as statoliths, are located only a few central cells of the ontogenetic youngest cell row. Beside the lateral root axis the two innermost statocytes contain a stable complex of rough endoplasmic reticulum, which is preferentially located in the central distal cell corner. In the statocytes lying above the lateral root axis the amyloplasts are sedimented on the ER-complex during growth in direction of the geotropic liminal angle. In the statocyte below the axis the ER-complex is free of amyloplasts. Thus a dorsiventrality exists in the statocytes located above and below the root axis in regard to the arrangement of their organelles.

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Herrn Professor Dr. Maximilian Steiner zum 70. Geburtstag.     

Comparative study of cellular structures implicated in gravisensing in statocytes of primary and lateral roots of Vigna angularis

Summary. The cellular structures of statocytes implicated in gravisensing in primary and lateral roots of Vigna angularis were compared. The statocytes of lateral roots already had small amyloplasts immediately after they emerged from the primary root. Although these amyloplasts sedimented, the lateral roots showed much weaker gravitropism than primary roots, at least until they reached a length of about 30 mm. The nuclei were usually positioned in the upper end of the statocytes in both types of roots. Electron microscopic surveys showed that many tubular elements of endoplasmic reticulum (ER) were frequently localized in the lower end of the statocyte and they sometimes diverged or curved, suggesting that the ER forms a large reticulate complex. It is worth noting that statocytes with a large ER complex were found much more frequently in primary roots than in lateral roots. The amyloplasts were not always settled on this complex but were very frequently under it, especially in the primary roots. In lateral roots, they were usually localized under the ER complex when they were present. Thus, it is suggested that the differential development and organization of the amyloplast-ER complex system is involved in the differential gravitropism of the two types of roots. Correspondence and reprints: Department of Biology, Faculty of Science, Ehime University, Bunkyo-cho, Matsuyama 790-8577, Japan.     

Induction of gravity-dependent plasmatic responses in root statocytes by short time contact between amyloplasts and the distal endoplasmic reticulum complex

Statocytes from roots of Lepidium sativum L., which developed after a 2-min soaking on a horizontal clinostat (2 rotations per min) for 44 h, exhibit the same polarity as in vertically grown roots, as indicated by a complex of endoplasmic reticulum (ER) cisternae at the distal cell pole. Amyloplasts are distributed randomly. The kinetics of graviresponse (=curvature) of such roots are identical to those of normally grown roots. Ten-minute exposure of the root, after 24 h development on the clinostat with gravity acting towards the root's basis (inversion), induces no changes in statocyte ultrastructure. However, corresponding exposure in normal orientation leads to subsequent disintegration of the distal ER complex, loss of amyloplast starch, confluence of lipid droplets, and an increase of the lytic compartment. These ultrastructural events thus appear to be induced by a physical contact — however short — between amyloplasts and the distal ER complex.Abbreviation ER endoplasmic reticulum Dedicated to Professor Dr. W. Haupt on the occasion of his 60th birthday     

A polarized cell: the root statocyte

In the gravity-perceiving cells (statocytes), located in the centre of the root cap, polarity is expressed in the arrangement of the organelles since, in most genera, the nucleus and the endoplasmic reticulum are maintained at the opposite ends of each cell by actin. Polarity is also evident in the distribution of plasmodesmata, which are more numerous in the transverse walls than in the longitudinal walls. The centre of each statocyte is depleted of microtubules (they are only located at the periphery) but is occupied by numerous amyloplasts (statoliths), denser than the cytoplasm. The amyloplasts do not contribute to the inherent structural polarity since their position is dependent upon the gravity vector. This article focuses on new microscopic analyses and on data obtained from experiments performed in microgravity, which have contributed to our better understanding of the architecture of the actin web implicated in the perception of gravity. Depending upon the plant, the actin network seems to be formed of single filaments arranged in various ways, or, of thin bundles of actin filaments. The amyloplasts are enmeshed in this web of actin and their envelopes are associated with it, but they can have autonomous movement via myosin in the absence of gravity. From calculations of the value of the force necessary to move one amyloplast in the lentil root, and from videomicroscopy performed with living statocytes of maize roots, it is hypothesized that actin microfilaments could be orientated in an overall diagonal direction in the statocyte. These observations could help in understanding how slight amyloplast movements may trigger and transmit the gravitropic signal.     

Morphology and ultrastructure of the gravity-sensitive leaf sheath base of the grass Echinochloa colonum L

When a flowering stalk of Echinochloa colonum is held horizontally, growth is initiated in the lower side of each leaf sheath base, restoring the inflorescence to an upright position. Changes in the gravity vector are perceived by specialised statolithcontaining tissue which is associated with each of the symmetrically-arranged vascular bundles within the leaf sheath bases. The morphological and ultrastructural features of these gravity-sensitive regions have been examined by light and electron microscopy. Each statocyte cell contains a large central vacuole with a thin lining of cytoplasm. Up to 50 spherical starch statoliths lie along the lowermost side of the cells and these sediment readily following geotropic stimulation. Statoliths are found in contact with the plasmalemma, or may be prevented from touching it by bands of microtubules. Dictyosomes and mitochondria are numerous, but endoplasmic reticulum is sparse. The nuclei tend to remain at the original apex of each cell. Statocytes of the leaf sheath base are compared and contrasted with those of the root tip.Abbreviations GMA glycol methacrylate - PAS periodic acid-Schiff's reagent - ER endoplasmic reticulum     

Root system architecture and gravity perception of a mangrove plant,Sonneratia alba J. Smith

We describe the features of the root system and the gravitropism of roots produced bySonneratia alba. The root system consists of four root types with different growth directions: (a) Pneumatophores, which are negatively orthogravitropic and their statocytes are very large (922 μm²) and the statolith is located near the proximal wall, (b) Cable roots and (c) Feeding roots which are both diagravitropic and their statoliths are settled along the longitudinal wall, and (d) Anchor roots which are positively orthogravitropic. The statocyte cells are the smallest (420 μm²) and statoliths settled at the distal wall. We found that all roots with marked gravitropism have statoliths that settle along different walls of the statocyte. This implies that the statoliths sensing of gravity is done by gravity on mass, and that they are denser than surrounding cytoplasm and this position is related to root growth direction. This finding matches the statoliths sediment under the effect of gravity. Irrespective of statolith, position and direction of growth may be stable.     

Microtubular configurations during the cellularization of coenocytic endosperm in Ranunculus sceleratus L.

Summary Endosperm cellularization in Ranunculus sceleratus was studied in terms of the initiation of cell-wall formation in the coenocytic endosperm. The first endosperm cell walls were in an anticlinal position relative to the cell wall of the embryo sac and originated from the cell plates and not from wall ingrowths from the embryo-sac wall itself. Alveolar endosperm was formed 3 days after pollination. Microtubules were associated with the freely growing wall ends of the anticlinal walls and were observed in various orientations that generally ranged from angles of 45 ° to 90 ° to the plane of the wall. They were absent in the regions where vesicles had already fused. These microtubules may function in maintaining the growth and the direction of growth of the anticlinal wall until cellularization is completed. At the site where three neighbouring alveoli share their freely growing wall ends, remarkable configurations of microtubules were observed: in each alveolus, microtubules ran predominantly parallel to the bisector of the angle formed by the common walls. These microtubules may form a physically stable framework and maintain the direction of growth of the wall edges. It is concluded that the growing edge of the anticlinal endosperm wall and its associated microtubules are a special continuum of the original phragmoplast that gave rise to the anticlinal wall.     

Concanavalin A binds to the endoplasmic reticulum and the starch grain surface of root statocytes

Using Concanavalin A (Con A) labeled with fluorescein isothiocyanate, we studied the intracellular localization of receptor molecules in the calyptra of 24-h dark-grown cress roots. Fixation in glutaraldehyde gave positive binding of the distal complex of the endoplasmic reticulum and the nucelus in the statocytes. In contrast, fixation in formaldehyde did not preserve the membrane-associated receptors, but revealed Con A affinity of the starch grain surface within the amyloplasts. Treatment of glutaraldehydefixed sections with non-ionic detergents led to partial solubilization of membrane components: the starch grain surface turned positive, though the positive binding of Con A to the endoplasmic reticulum and the nucleus remained unaffected. We therefore conclude that the Con A receptor in the membrane is a glycoprotein tightly inserted in other components of the compartment.Abbreviations Con A Concanavalin A - ER endoplasmic reticulum - FITC fluorescein isothiocyanate - NP 40 nonidet P40     

The polarity of statocytes and the gravisensitivity of roots are dependent on the concentration of calcium in statocytes

In order to examine a possible role of calcium in graviperception, the calcium ionophore A23187 was used to elevate the concentration of free cytoplasmic calcium in statocytes of the roots of Lepidium sativum L. After a brief incubation (30 min) in a medium that contained 10 micromoles A23187 and 5.5 micromoles CaCl2, 50% of the roots bent gravitropically during a subsequent 2 h of horizontal exposure, with an angle of curvature that varied from 5 degrees to 70 degrees. The corresponding statocytes exhibited a polar arrangement of cell organelles as did the controls. However, in statocytes from 50% of the roots which were not curved after gravistimulation a portion of the distal endoplasmic reticulum (ER) complex was displaced in the direction of gravity within 30 min of horizontal exposure. After washing of the briefly treated roots for 24 h with 1% dimethylsulfoxide the percentage of gravitropically bending roots increased to approximately 80%, but the angle of curvature amounted to only 5 degrees-10 degrees. Longer treatment (2 h) with A23187 caused a complete loss of graviresponsiveness which was accompanied by disintegration of statocyte polarity. We concluded from these results that i) calcium is involved in graviperception and ii) gravisensitivity depends on the integrity of statocytes.     

The Mechanism of Geoperception in Lentil Roots

The sediment of the amyloplasts in the statocytes of lentilroots was analysed in two different samples of seedlings. Theroots of the first sample (HP) were grown in a horizatal position,whereas thoes of the second sample (VP+20) were grown in a horizontalposition and then exposure to give a response). It is demonstratedthat the statolish can almost enter into contact with the plasmamembrane lining the longitudinal wall of the statocytes of theHP sample. However, these organelles in the VP+20 sample areable to provoke a geotropic stimulation though they are sedimentedat a distance of 0.1350–0.2600 µm from the plasmalemma.From these data it is concluded that the cytoplasmic structureswhich may play a role in the geotropic stimulation are: (1)the endoplasmic reticulum located along the longitudianl wallof the statocytes and (2) the microtubules or the plasmalemmaif the action of the statoliths is transmitted by the parietalcytoplasm. The large aggregations of endoplasmic reticulum whichare situated in the distal part of the central root cap cellswould not have any role in the perception of gravity by roots.These results are discussed in the light of recent work showingthe action of a growth inibitor in the geotropic reaction ofroots.     

Polarity of statocytes in lentil seedling roots grown in space (Spacelab D1 Mission)

A morphometric analysis of root statocytes was performed on seedlings of lentil ( Lens culinaris L., cv. Verte du Puy) in order to determine the effects of microgravity on the polarity of these cells. Seedlings were grown: (1) on the ground, (2) in microgravity, (3) on a 1 g centrifuge in space, (4) first in microgravity and then placed on a 1 g centrifuge for 3 h. Dry seeds were hydrated in space (except for the ground control) for 25 h in darkness at 22°C in the Biorack facility developed by the European Space Agency. At the end of the experiment, the seedlings were photographed and fixed in glutaraldehyde in the Biorack glove box. The average shape of the statocytes and the location of endoplasmic reticulum, amyloplasts and nucleus in the cells were analysed in the four samples. By considering the cell shape, it appears that the morphology of the statocytes on the ground was different from that observed in the space samples. Cell polarity was similar in microgravity and in the centrifuged samples except for the distribution of the amyloplasts. These organelles were not distributed at random in near zero gravity, and they were more numerous in the proximal than in the distal half. Moreover, the statoliths were more voluminous in microgravity than in the centrifuged samples. The nucleus was closer to the cell center in the statocytes of roots grown in microgravity than in statocytes of roots grown in microgravity and then placed on the 1 g centrifuge for 3 h. It is hypothesized that the nucleus is attached to the cell periphery and that its location is dependent upon gravity.