Your search keyword '"Chlorophyta ultrastructure"' showing total 12 results

1. Characterization of the responses to saline stress in the symbiotic green microalga Trebouxia sp. TR9.

Author

Hinojosa-Vidal E, Marco F, Martínez-Alberola F, Escaray FJ, García-Breijo FJ, Reig-Armiñana J, Carrasco P, and Barreno E

Subjects

Abscisic Acid metabolism, Ascomycota genetics, Ascomycota ultrastructure, Chlorophyta genetics, Chlorophyta microbiology, Chlorophyta ultrastructure, Lichens genetics, Lichens microbiology, Lichens ultrastructure, Microalgae genetics, Microalgae microbiology, Microalgae ultrastructure, Photosynthesis drug effects, Plant Growth Regulators metabolism, Salinity, Sodium Chloride pharmacology, Stress, Physiological, Ascomycota physiology, Chlorophyta physiology, Lichens physiology, Microalgae physiology, Symbiosis

Abstract

Main Conclusion: For the first time we provide a study on the physiological, ultrastructural and molecular effects of salt stress on a terrestrial symbiotic green microalga, Trebouxia sp. TR9. Although tolerance to saline conditions has been thoroughly studied in plants and, to an extent, free-living microalgae, scientific data regarding salt stress on symbiotic lichen microalgae is scarce to non-existent. Since lichen phycobionts are capable of enduring harsh, restrictive and rapidly changing environments, it is interesting to study the metabolic machinery operating under these extreme conditions. We aim to determine the effects of prolonged exposure to high salt concentrations on the symbiotic phycobiont Trebouxia sp. TR9, isolated from the lichen Ramalina farinacea. Our results suggest that, when this alga is confronted with extreme saline conditions, the cellular structures are affected to an extent, with limited chlorophyll content loss and photosynthetic activity remaining after 72 h of exposure to 5 M NaCl. Furthermore, this organism displays a rather different molecular response compared to land plants and free-living halophile microalgae, with no noticeable increase in ABA levels and ABA-related gene expression until the external NaCl concentration is raised to 3 M NaCl. Despite this, the ABA transduction pathway seems functional, since the ABA-related genes tested are responsive to exogenous ABA. These observations could suggest that this symbiotic green alga may have developed alternative molecular pathways to cope with highly saline environments.

Published

2018

2. 3D reconstruction of endoplasmic reticulum in a hydrocarbon-secreting green alga, Botryococcus braunii (Race B).

Author

Suzuki R, Nishii I, Okada S, and Noguchi T

Subjects

Chlorophyta metabolism, Endoplasmic Reticulum physiology, Microscopy, Electron, Microscopy, Fluorescence, Organelles physiology, Organelles ultrastructure, Chlorophyta ultrastructure, Endoplasmic Reticulum ultrastructure, Hydrocarbons metabolism, Imaging, Three-Dimensional methods

Abstract

Main Conclusion: Based on 3D sections through cells of Botryococcus braunii, the structure of three domains of endoplasmic reticulum, and their spatial and functional relationships to other organelles are clarified. Oil production by photosynthetic microalgae has attracted attention since these oils can be converted into renewable, carbon-neutral fuels. The green alga B. braunii accumulates large amounts of hydrocarbons, 30-50% of cell dry weight, in extracellular spaces rather than its cytoplasm. To advance the knowledge of hydrocarbon biosynthesis and transport pathways in this alga, we utilized transmission EM combined with rapid freezing and image reconstruction. We constructed detailed 3D maps distinguishing three ER domains: rdER with ribosomes on both sides, rsER with ribosomes on one side, and sER without ribosomes. The rsER and sER domains were especially prominent during the oil body formation and oil secretion stages. The ER contacted the chloroplasts, oil bodies, or plasma membrane via the rsER domains, oriented with the ribosome-free surface facing the organelles. We discuss the following transport pathway for hydrocarbons and their precursors in the cytoplasm: chloroplast → endoplasmic reticulum (ER) → oil bodies → ER → plasma membrane → secretion. This study represents the first 3D study of the three-domain classification (rdER, rsER and sER) of the ER network among eukaryotic cells. Finally, we propose the novel features of the ERs in plant cells that are distinct from the latest proposed model for the ERs in mammalian cells.

Published

2018

3. Patterns of asexual reproduction in Nannochloris bacillaris and Marvania geminata (Chlorophyta, Trebouxiophyceae).

Author

Yamamoto M, Nishikawa T, Kajitani H, and Kawano S

Subjects

Actins genetics, Cell Wall ultrastructure, Chlorophyta genetics, Chlorophyta ultrastructure, Cryoelectron Microscopy, Fluorescent Dyes, Microscopy, Electron, Transmission, Phylogeny, Sequence Analysis, DNA, Cell Cycle physiology, Cell Wall physiology, Chlorophyta physiology, Reproduction, Asexual physiology

Abstract

Non-flagellated vegetative green algae of the Trebouxiophyceae propagate mainly by autosporulation. In this manner, the mother cell wall is shed following division of the protoplast in each round of cell division. Binary fission type Nannochloris and budding type Marvania are also included in the Trebouxiophyceae. Phylogenetic trees based on the actin sequences of Trebouxiophyceae members revealed that the binary fission type Nannochloris bacillaris and the budding type Marvania geminata are closely related in a distal monophyletic group. Our results suggest that autosporulation is the ancestral mode of cell division in Trebouxiophyceae. To elucidate how non-autosporulative mechanisms such as binary fission and budding evolved, we focused on the cleavage of the mother cell wall. Cell wall development was analyzed using a cell wall-specific fluorescent dye, Fluostain I. Exfoliation of the mother cell wall was not observed in either N. bacillaris or M. geminata. We then compared the two algae by transmission electron microscopy with rapid freeze fixation and freeze substitution; in both algae, the mother cell wall was cleaved at the site of cell division, but remained adhered to the daughter cell wall. In N. bacillaris, the cleaved mother cell wall gradually degenerated and was not observed in the next cell cycle. In contrast, M. geminata daughter cells entered the growth phase of the next cell cycle bearing the mother and grandmother cell walls, causing the uncovered portion of the plane of division to bulge outward. Such a delay in the degeneration and shedding of the mother cell wall probably led to the development of binary fission and budding.

Published

2007

4. Late type of daughter cell wall synthesis in one of the Chlorellaceae, Parachlorella kessleri (Chlorophyta, Trebouxiophyceae).

Author

Yamamoto M, Kurihara I, and Kawano S

Subjects

Cell Cycle physiology, Cell Wall ultrastructure, Chlorophyta physiology, Chlorophyta ultrastructure, Species Specificity, Spores physiology, Spores ultrastructure, Cell Wall metabolism, Chlorophyta metabolism

Abstract

Autosporulation is a common mode of propagation for unicellular algae. Autospore-forming species of Chlorellaceae, Chlorella vulgaris Beijerinck, C. sorokiniana Shihira et Krauss, C. lobophora Andreyeva, and Parachlorella kessleri (Fott et Nováková) Krienitz et al. have glucosamine as the main constituent of their rigid cell wall. Recent phylogenetic analyses have showed that the Chlorellaceae divided into two sister groups: the Chlorella-clade and the Parachlorella-clade. We compared the cell wall structure and synthesis of the daughter cell wall in the four species by electron microscopy using rapid freezing and freeze substitution methods. The cell wall of C. vulgaris, C. sorokiniana, and C. lobophora consisted of an electron-dense thin layer with an average thickness of 17-20, 22, and 19 nm, respectively. In these three species, daughter cell wall synthesis occurred on the outer surface of the plasma membrane in the early cell-growth phase. The cell wall of P. kessleri, however, was electron-transparent and 54-59 nm in thickness. Ruthenium red staining of P. kessleri indicated that ruthenium-red-specific polysaccharides accumulated over the outer surface of the plasma membrane. Immunoelectron microscopic observation with an anti-beta-1, 3-glucan antibody and staining with wheat germ agglutinin (WGA) indicated that the cell wall contained beta-1, 3-glucan and WGA specific N-acetyl-beta-D-glucosamine. In P. kessleri, daughter cell wall synthesis began after successive protoplast division. The daughter cell wall synthesis during autosporulation in the four species of Chlorellaceae can be classified into two types-the early and the late types.

Published

2005

5. Subfractionation of eyespot apparatuses from the green alga Spermatozopsis similis: isolation and characterization of eyespot globules.

Author

Renninger S, Backendorf E, and Kreimer G

Subjects

Algal Proteins analysis, Algal Proteins drug effects, Carotenoids metabolism, Cell Fractionation, Cell Movement, Chlorophyll analysis, Chlorophyta chemistry, Chlorophyta ultrastructure, Endopeptidases metabolism, Light, Organelles chemistry, Organelles ultrastructure, Spectrum Analysis, Thermolysin pharmacology, Carotenoids analysis, Chlorophyta physiology, Organelles physiology

Abstract

Despite the well-characterized function of the green-algal eyespot apparatus as a combined absorption/reflection screen for the photoreceptor for phototaxis, little is known about the proteins involved in the formation of this complex organelle. We therefore purified the carotenoid-rich lipid globules, which are the most conspicuous component of the eyespot sensu strictu from Spermatozopsis similis Preisig et Melkonian. Electron microscopy and an average carotenoid:chlorophyll ratio of 51, confirmed the high purity of the fraction. The diameter of isolated globules (approx. 112 nm) fell within their in vivo range (90-120 nm). Absorption spectra in aqueous media peaked at 535 nm. The predominant carotenoids were beta/psi-, beta, beta- and delta-carotene. Freeze-fracture studies with cells and whole-mount electron microscopy of isolated globules demonstrated regularly arranged particles at the globule surface. Sodium dodecyl sulfate polyacrylamide gel electrophresis revealed specific enrichment of 10 tightly bound major proteins and several minor proteins with the globules. Proteases were used to analyze their topology and function. Upon treatment with thermolysin, globules were released from a fraction enriched in isolated eyespot apparatuses. Major proteins of these globules, and those treated with thermolysin after isolation, were identical. However, the purified proteins were sensitive to thermolysin, indicating that domains of them are normally hidden in the globule matrix. In contrast, pronase degraded all globule-associated proteins in situ. These globules were not stable and easily fused, whereas thermolysin-treated globules were relatively stable. Lipase did not affect globule stability. These results indicate that the five thermolysin-resistant proteins (apparent Mr values: 56, 52, 32, 29, 27 kDa) are close to the surface and might be crucial for globule stabilization, whereas the thermolysin-accessible proteins are probably involved in globule/globule interactions and/or globule/eyespot-membrane interactions.

Published

2001

6. The application of atomic force microscopy to topographical studies and force measurements on the secreted adhesive of the green alga Enteromorpha.

Author

Callow JA, Crawford SA, Higgins MJ, Mulvaney P, and Wetherbee R

Subjects

Cell Adhesion, Microscopy, Atomic Force methods, Microscopy, Electron, Scanning, Spores, Time Factors, Chlorophyta physiology, Chlorophyta ultrastructure

Abstract

Atomic force microscopy (AFM) enables the topographical structure of cells and biological materials to be resolved under natural (physiological) conditions, without fixation and dehydration artefacts associated with imaging methods in vacuo. It also provides a means of measuring interaction forces and the mechanical properties of biomaterials. In the present study, AFM has been applied for the first time to the study of the mechanical properties of a natural adhesive produced by a green plant cell. Swimming spores of the green alga Enteromorpha linza (L.) J. Ag. (7-10 microm) secrete an adhesive glycoprotein which provides firm anchorage to the substratum. Imaging of the adhesive in its hydrated state revealed a swollen gel-like pad, approximately 1 microm thick, surrounding the spore body. Force measurements revealed that freshly released adhesive has an adhesion strength of 173 +/- 1.7 mN m(-1) (mean +/- SE; n=90) with a maximum value for a single adhesion force curve of 458 mN m(-1). The adhesive had a compressibility (equivalent to Young's modulus) of 0.54 x 10(6) +/- 0.05 x 10(6) N m-2 (mean +/- SE; n=30). Within minutes of release the adhesive underwent a progressive 'curing' process with a 65% reduction in mean adhesive strength within an hour of settlement, which was also reflected in a reduction in the average length of the adhesive polymer strands (polymer extension) and a 10-fold increase in Young's modulus. Measurements on the spore surface itself revealed considerably lower adhesion-strength values but higher polymer-extension values than the adhesive pad, which may reflect the deposition of different polymers on this surface as a new cell wall is formed. The study demonstrates the value of AFM to the imaging of plant cells in the absence of fixation and dehydration artefacts and to the characterisation of the mechanical properties of plant glycoproteins that have potential utility as adhesives.

Published

2000

7. Presence of the CO2-concentrating mechanism in some species of the pyrenoid-less free-living algal genus Chloromonas (Volvocales, Chlorophyta).

Author

Morita E, Abe T, Tsuzuki M, Fujiwara S, Sato N, Hirata A, Sonoike K, and Nozaki H

Subjects

Carbonic Anhydrases metabolism, Chlorophyta enzymology, Chlorophyta ultrastructure, Microscopy, Electron methods, Pyrenes, Ribulose-Bisphosphate Carboxylase metabolism, Subcellular Fractions enzymology, Carbon Dioxide metabolism, Chlorophyta metabolism

Abstract

Physiological and morphological characteristics related to the CO2-concentrating mechanism (CCM) were examined in several species of the free-living, unicellular volvocalean genus Chloromonas (Chlorophyta), which differs morphologically from the genus Chlamydomonas only by lacking pyrenoids. The absence of pyrenoids in the chloroplasts of Chloromonas (Cr.) rosae UTEX 1337, Cr. serbinowii UTEX 492, Cr. clatharata UTEX 1970, Cr. rosae SAG 26.90, and Cr. palmelloides SAG 32.86 was confirmed by light and electron microscopy. In addition, immunogold electron microscopy demonstrated that ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco; EC 4.1.1.39) molecules were distributed almost evently throughout the chloroplasts in all five Chloromonas strains. However, Chloromonas exhibited two types of physiological characteristics related to the CCM depending on the species or strains examined. Chloromonas rosae UTEX 1337 and Cr. serbinowii had high photosynthetic affinities for CO2 in cells grown in culture medium bubbled with air (low-CO2 cells), compared with those grown in medium bubbled with 5% CO2 (high-CO2 cells), indicating the presence of the low-CO2-inducible CCM. In addition, these two Chloromonas strains exhibited low-CO2-inducible carbonic anhydrase (CA; EC 4.2.1.1) activity and seemed to have small intracellular inorganic carbon pools. Therefore, it appears that Cr. rosae UTEX 1337 and Cr. serbinowii possess the CCM as in pyrenoid-containing microalgae such as Chlamydomonas reinhardtii. By contrast, Cr. clatharata, Cr. rosae SAG 26.90 and Cr. palmelloides showed low photosynthetic affinities for CO2 when grown under both CO2 conditions. Moreover, these three strains exhibited an apparent absence of intracellular inorganic carbon pools and lacked low-CO2-inducible CA activity. Thus, Cr. clatharata, Cr. rosae SAG 26.90 and Cr. palmelloides, like other pyrenoid-less algae (lichen photobionts) reported previously, seem to lack the CCM. The present study is the first demonstration of the CCM in pyrenoid-less algae, indicating that pyrenoids or accumulation of Rubisco in the chloroplasts are not always essential for the CCM in algae. Focusing on this type of CCM in pyrenoid-less algae, the physiological and evolutionary significance of pyrenoid absence is discussed.

Published

1998

8. Anomalous gravitropic response of Chara rhizoids during enhanced accelerations.

Author

Braun M

Subjects

Actins physiology, Centrifugation, Chlorophyta growth & development, Microscopy, Electron, Plastids physiology, Time Factors, Acceleration, Chlorophyta ultrastructure, Endoplasmic Reticulum physiology, Gravitropism, Hypergravity

Abstract

Centrifugal accelerations of 50-250 g were applied to rhizoids of Chara globularis Thuill. at stimulation angles (alpha) of 5-90 degrees between the acceleration vector and the rhizoid axis. After the start of centrifugation, the statoliths were pressed asymmetrically onto the centrifugal flank of the apical cell wall. In contrast to the well-known bending (by bowing) under 1 g, the rhizoids responded in two distinct phases. Following an initial phase of sharp bending (by bulging), which is similar to the negatively gravitropic response of Chara protonemata, rhizoids stopped bending and, in the second phase, grew straight in directions clearly deviating from the direction of acceleration. These response angles (beta) between the axis of the bent part of the rhizoid and the acceleration vector were strictly correlated with the g-level of acceleration. The higher the acceleration the greater was beta. Except for the sharp bending, the shape and growth rate of the centrifuged rhizoids were not different from those of gravistimulated control rhizoids at 1 g. These results indicate that gravitropic bending of rhizoids during enhanced accelerations (5 degrees < or = alpha < or = 90 degrees) is caused not only by subapical differential flank growth, as it is the case at 1 g, but also by also by the centripetal displacement of the growth centre as was recently discussed for the negative gravitropism of Chara protonemata. A hypothesis for cytoskeletally mediated polar growth is presented based on data from positive gravitropic bending of Chara rhizoids at 1 g and from the anomalous gravitropic bending of rhizoids compared with the negatively gravitropic bending of Chara protonemata. The data obtained are also relevant to a general understanding of graviperception in higher-plant organs.

Published

1996

9. Micromanipulation of statoliths in gravity-sensing Chara rhizoids by optical tweezers.

Author

Leitz G, Schnepf E, and Greulich KO

Subjects

Actins drug effects, Chlorophyta drug effects, Chlorophyta physiology, Chlorophyta radiation effects, Cytochalasin B pharmacology, Cytological Techniques, Infrared Rays, Microscopy, Optics and Photonics instrumentation, Actins physiology, Chlorophyta ultrastructure, Gravitropism, Gravity Sensing, Lasers, Micromanipulation

Abstract

Infrared laser traps (optical tweezers) were used to micromanipulate statoliths in gravity-sensing rhizoids of the green alga Chara vulgaris Vail. We were able to hold and move statoliths with high accuracy and to observe directly the effects of statolith position on cell growth in horizontally positioned rhizoids. The first step in gravitropism, namely the physical action of gravity on statoliths, can be simulated by optical tweezers. The direct laser microirradiation of the rhizoid apex did not cause any visible damage to the cells. Through lateral positioning of statoliths a differential growth of the opposite flank of the cell wall could be induced, corresponding to bending growth in gravitropism. The acropetal displacement of the statolith complex into the extreme apex of the rhizoid caused a temporary decrease in cell growth rate. The rhizoids regained normal growth after remigration of the statoliths to their initial position 10-30 micrometers basal to the rhizoid apex. During basipetal displacement of statoliths, cell growth continued and the statoliths remigrated towards the rhizoid tip after release from the optical trap. The resistance to statolith displacement increased towards the nucleus. The basipetal displacement of the whole complex of statoliths for a long distance (>100 micrometers) caused an increase in cell diameter and a subsequent regaining of normal growth after the statoliths reappeared in the rhizoid apex. We conclude that the statolith displacement interferes with the mechanism of tip growth, i.e. with the transport of Golgi vesicles, either directly by mechanically blocking their flow and/or, indirectly, by disturbing the actomyosin system. In the presence of the actin inhibitor cytochalasin B the optical forces required for acropetal and basipetal displacement of statoliths were significantly reduced to a similar level. The lateral displacement of statoliths was not changed by cytochalasin B. The results indicate: (i) the viscous resistance to optical displacement of statoliths depend mainly on actin, (ii) the lateral displacement of statoliths is not impeded by actin filaments, (iii) the axially directed actin-mediated forces against optical displacement of statoliths (for a distance of 10 micrometers) are stronger in the basipetal than in the acropetal direction, (iv) the forces acting on single statoliths by axially oriented actin filaments are estimated to be in the range of 11-110 pN for acropetal and of 18-180 pN for basipetal statolith displacements.

Published

1995

10. Negative gravitropism in Chara protonemata: a model integrating the opposite gravitropic responses of protonemata and rhizoids.

Author

Hodick D

Subjects

Actin Cytoskeleton physiology, Chlorophyta growth & development, Cytochalasin B pharmacology, Gravitation, Gravitropism drug effects, Plastids drug effects, Time Factors, Chlorophyta ultrastructure, Gravitropism physiology, Plastids physiology

Abstract

The unicellular protonema of Chara fragilis Desv. was investigated in order to establish a reaction chain for negative gravitropism in tip-growing cells. The time course of gravitropic bending after stimulation at angles of 45 degrees or 90 degrees showed three distinct phases of graviresponse. During the first hour after onset of stimulation a strong upward shift of the tip took place. This initial response was followed by an interval of almost straight growth. Complete reorientation was achieved in a third phase with very low bending rates. Gravitropic reorientation could be completely abolished by basipetal centrifugation of the cells, which lastingly removed conspicuous dark organelles from the protonema tip, thus identifying them as statoliths. Within minutes after onset of gravistimulation most or all statoliths were transported acropetally from their resting position 20-100 micrometers from the cell apex to the lower side of the apical dome. This transport is actin-dependent since it could be inhibited with cytochalasin B. Within minutes after arrival of the statoliths, the apical dome flattened on its lower side and bulged on the upper one. After this massive initial response the statoliths remained firmly sedimented, but the distance between this sedimented complex and the cell vertex increased from 7 micrometers to 22 micrometers during the first hour of stimulation and bending rates sharply declined. From this it is concluded that only statoliths inside the apical dome convey information about the spatial orientation of the cell in the gravitropic reaction chain. After inversion of the protonema the statoliths transiently arranged into a disk-shaped complex about 8 micrometers above the vertex. When this statolith complex tilted towards one side of the apical dome, growth was shifted in the opposite direction and bending started. It is argued that the statoliths intruding into the apical dome may displace a growth-organizing structure from its symmetrical position in the apex and may thus cause bending by bulging. In the positively gravitropic Chara rhizoids only a more stable anchorage of the growth-organizing structure is required. As a consequence, sedimented statoliths cannot dislocate this structure from the vertex. Instead they obstruct a symmetrical distribution of cell-wall-forming vesicles around the structure and thus cause bending by bowing.

Published

1994

11. Oriented movement of statoliths studied in a reduced gravitational field during parabolic flights of rockets.

Author

Volkmann D, Buchen B, Hejnowicz Z, Tewinkel M, and Sievers A

Subjects

Actin Cytoskeleton physiology, Brassicaceae ultrastructure, Chlorophyta ultrastructure, Cytoskeleton physiology, Endoplasmic Reticulum physiology, Hypergravity, Microscopy, Electron, Plant Roots ultrastructure, Plastids physiology, Brassicaceae physiology, Chlorophyta physiology, Gravity Sensing physiology, Plant Roots physiology, Space Flight, Weightlessness

Abstract

During five rocket flights (TEXUS 18, 19, 21, 23 and 25), experiments were performed to investigate the behaviour of statoliths in rhizoids of the green alga Charo globularia Thuill. and in statocytes of cress (Lepidium sativum L.) roots, when the gravitational field changed to approx. l0(-4) g (i.e. microgravity) during the parabolic flight (lasting for 301-390 s) of the rockets. The position of statoliths was only slightly influenced by the conditions during launch, e.g. vibration, acceleration and rotation of the rocket. Within approx. 6 min of microgravity conditions the shape of the statolith complex in the rhizoids changed from a transversely oriented lens into a longitudinally oriented spindle. The center of the statolith complex moved approx. 14 micrometers and 3.6 micrometers in rhizoids and root statocytes, respectively, in the opposite direction to the originally acting gravity vector. The kinetics of statolith displacement in rhizoids demonstrate that the velocity was nearly constant under microgravity whereas it decreased remarkably after inversion of rhizoids on Earth. It can be concluded that on Earth the position of statoliths in both rhizoids and root statocytes depends on the balance of two forces, i.e. the gravitational force and the counteracting force mediated by microfilaments.

Published

1991

12. Statoliths and microfilaments in plant cells.

Author

Sievers A, Kruse S, Kuo-Huang LL, and Wendt M

Subjects

Actin Cytoskeleton drug effects, Actins physiology, Brassicaceae drug effects, Brassicaceae physiology, Chlorophyta drug effects, Chlorophyta physiology, Cytochalasin B pharmacology, Endoplasmic Reticulum physiology, Gravitropism physiology, Gravity Sensing drug effects, Plant Roots drug effects, Plant Roots physiology, Plant Roots ultrastructure, Plastids drug effects, Actin Cytoskeleton physiology, Brassicaceae ultrastructure, Chlorophyta ultrastructure, Gravity Sensing physiology, Plastids physiology

Abstract

Microfilaments have been demonstrated in rhizoids of Chara fragilis Desvaux by labelling of actin with rhodamine-conjugated phalloidin. Each rhizoid contains thick microfilament-bundles arranged longitudinally in the basal region. In the subapical and apical regions, much thinner bundles exist which contact the statoliths and encircle them in the form of a dense envelope. In root statocytes from Lepidium sativum L. the presence of an actin network is indicated by the fact that application of cytochalasin B (25 micrograms ml-1 for 4 h) results in an approximately threefold increase in the rate of statolith (amyloplast) sedimentation relative to controls. It is concluded that in gravity-perceiving plant cells statoliths may trigger the transduction mechanism via actin filaments.

Published

1989