A barrier to diffusion in pseudoplasmodia of Dictyostelium discoideum

Several enzymatic activities have been reported to be preferentially localized in the anterior portions of pseudoplasmodia of Dictyostelium discoideum. Since anterior cells are responsible for formation of the stalk during fruiting body construction, it has been suggested that accumulation of these enzymes may direct the cells toward stalk differentiation. However, the evidence for enzyme localization has come only from histochemical studies. We have assayed for succinoxidase and several dehydrogenase activities in cell free extracts of isolated anterior and posterior fragment and found no significant differences in specific activities, although by histochemical techniques each is apparently localized in the anterior cells. The preferential staining appears to be a consequence of a barrier to diffusion that is more effective at the back than at the front in limiting entry of the histochemical chromogen into pseudoplasmodia. The barrier appears to be the glycoprotein surface sheath that surrounds the pseudoplasmodium. The consequences of a barrier to diffusion of compounds into and out of pseudoplasmodia are discussed in relation to a mechanism that could give cells information concerning their position in this organism.     

Analytical studies on migrating movement of the pseudo-plasmodium ofDictyostelium discoideum

Summary Migrating movement of a pseudoplasmodium (slug) of the cellular slime mouldDictyostelium discoideum was analyzed using a time-lapse video tape recorder. Since slugs usually migrated with repeated interruptions of advance, migrating velocities were measured only within a period of forward movement. On the basis of some known facts and assumptions, a dynamical model for slug movement was formulated, which consists of motive force generated by slug cells against their intrinsic resistance and resistance of slime sheath at the tip. The migrating velocity of a slug depended neither on its width nor its volume, but solely on its length. Under any experimental conditions tested, a linear relationship always held between reciprocals of the two variables. The results were in good agreement with predictions of the model. Quantitative analyses of experimental results by the use of the model lead to the conclusions that a decrease in velocity at a low temperature is due to an increase in resistance of slime sheath at the tip, but that a decrease in velocity during prolonged migration is due to a decrease in motive force of constituent cells. An anterior isolate dissected from a slug migrated at a velocity greater than that of an intact slug of the same length. This was interpreted by the model to be due to the fact that the anterior cells have greater motive forces and intrinsic resistances than the posterior cells. The heterogeneous distributions of the two variables in the cell mass is discussed in reference to the mechanism of sorting out of cells.     

Aerial migration of the Dictyostelium slug

The Dictyostelium slug lays down curved marks in its slime sheath trail as it migrates across an agar substrate. These 'footprints' are caused by elevation of the slug anterior as it initiates a period of aerial migration and can be used as a measure of the slug's propensity for this behavior. A variety of factors have been found to affect the number of footprints created per distance migrated. Smaller slugs produce a higher incidence of footprints than larger slugs. Migration in the light and lower temperatures during migration increase footprint incidence. Activated charcoal reduces, while exogenous addition of ammonia increases, the incidence of footprints. Simulation of the three-dimensional (3D) environment of the soil suggests that aerial migration plays a role in the slug's movement through the cavities of its natural environment. A model proposes that aerial migration is initiated by a small group of continually changing prestalk cells that acts as a pacemaker and is moved around the circumference of the slug tip by the rotation of the prestalk cells. As this pacemaker reaches the upper surface of the slug it can initiate aerial migration.     

Pattern Formation in Dictyostelium discoideum: Temporal and Spatial Distribution of Prespore Vacuoles

Cell differentiation, cell determination and pattern formation in the pseudoplasmodium of Dictyostelium discoideum , was investigated using the prespore specific vacuole (PV) as a morphological marker. Concomitantly, measurements of cell movement within the pseudoplasmodium were made by tracing radioactively labelled cells. The main results indicate that 1) prespore cells appear first during late aggregation and occur randomly throughout the pseudoplasmodium with the exception of the very tip which stays free of prespore cells throughout development; 2) after late aggregation the number of prespore cells increases over a period of several hours; 3) each prespore cell takes on a progressively more prespore-like character as judged by the increase in number of PVs it contains; 4) establishment of the distribution pattern of prespore and prestalk cells takes place within the first 2 h, mainly by a sorting out mechanism; 5) presumptive spore areas are likely to contain a small proportion of cells lacking PVs (prestalk-cells?) while presumptive stalk cell areas are homogeneous throughout; 6) maintenance of the pattern during migration may be facilitated by a circulation at low level of prestalk cells between prestalk and prespore areas; and 7) during the development of this organism the events of cell determination, cell differentiation and pattern formation overlap substantially in time.     

Origin and role of distal visceral endoderm, a group of cells that determines anterior-posterior polarity of the mouse embryo

Anterior-posterior polarity of the mouse embryo has been thought to be established when distal visceral endoderm (DVE) at embryonic day (E) 5.5 migrates toward the future anterior side to form anterior visceral endoderm (AVE). Lefty1, a marker of DVE and AVE, is asymmetrically expressed in implanting mouse embryos. We now show that Lefty1 is expressed first in a subset of epiblast progenitor cells and then in a subset of primitive endoderm progenitors. Genetic fate mapping indicated that the latter cells are destined to become DVE. In contrast to the accepted notion, however, AVE is not derived from DVE but is newly formed after E5.5 from Lefty1(-) visceral endoderm cells that move to the distal tip. Concomitant with DVE migration, all visceral endoderm cells in the embryonic region undergo global movement. In embryos subjected to genetic ablation of Lefty1-expressing DVE cells, AVE was formed de novo but the visceral endoderm including the newly formed AVE failed to migrate, indicating that DVE guides the migration of AVE by initiating the global movement of visceral endoderm cells. Future anterior-posterior polarity is thus already determined by Lefty1(+) blastomeres in the implanting blastocyst.     

Active cell migration drives the unilateral movements of the anterior visceral endoderm

The anterior visceral endoderm (AVE) of the mouse embryo is a specialised extra-embryonic tissue that is essential for anterior patterning of the embryo. It is characterised by the expression of anterior markers such as Hex, Cerberus-like and Lhx1. At pre-gastrula stages, cells of the AVE are initially located at the distal tip of the embryo, but they then move unilaterally to the future anterior. This movement is essential for converting the existing proximodistal axis into an anteroposterior axis. To investigate this process, we developed a culture system capable of imaging embryos in real time with single cell resolution. Our results show that AVE cells continuously change shape and project filopodial processes in their direction of motion, suggesting that they are actively migrating. Their proximal movement stops abruptly at the junction of the epiblast and extra-embryonic ectoderm, whereupon they move laterally. Confocal microscope images show that AVE cells migrate as a single layer in direct contact with the epiblast, suggesting that this tissue might provide directional cues. Together, these results show that the anteroposterior axis is correctly positioned by the active movement of cells of the AVE in response to cues from their environment, and by a 'barrier' to their movement that provides an endpoint for this migration.     

Differential positioning of chloroplasts in C4 mesophyll and bundle sheath cells

Chloroplast photorelocation movement is extensively studied in C₃ but not C₄ plants. C₄ plants have two types of photosynthetic cells: mesophyll and bundle sheath cells. Mesophyll chloroplasts are randomly distributed along cell walls, whereas bundle sheath chloroplasts are located close to the vascular tissues or mesophyll cells depending on the plant species. The cell-specific C₄ chloroplast arrangement is established during cell maturation, and is maintained throughout the life of the cell. However, only mesophyll chloroplasts can change their positions in response to environmental stresses. The migration pattern is unique to C₄ plants and differs from that of C₃ chloroplasts. in this mini-review, we highlight the cell-specific disposition of chloroplasts in C₄ plants and discuss the possible physiological significances.Key words: abscisic acid, aggregative movement, avoidance movement, blue light, bundle sheath cell, C₄ plant, chloroplast, cytoskeleton, environmental stress, mesophyll cellChloroplasts can change their intracellular positions to optimize photosynthetic activity and/or reduce photodamage occurring in response to light irradiation. On treating with high-intensity light, the chloroplasts move away from the light to minimize photodamage (avoidance response). Meanwhile, on irradiating with low-intensity light, they move toward the light source to maximize photosynthesis (accumulation response). These chloroplast-photorelocation movements are observed in a wide variety of plant species from green algae to seed plants,^1–3 although little attention has been paid to C₄ plants. There is a report stating that monocotyledonous C₄ plants showed changes in the light transmission of leaves in response to blue light,⁴ although the direction of migration of the chloroplasts is not described.C₄ plants have two types of photosynthetic cells: mesophyll (M) cells and bundle sheath (BS) cells, which have numerous well-developed chloroplasts. BS cells surround the vascular tissues, while M cells encircle the cylinders of the BS cells (Fig. 1). The C₄ dicarboxylate cycle of photosynthetic carbon assimilation is distributed between the two cell types, and acts as a CO₂ pump to concentrate CO₂ in the BS chloroplasts.^5,6 C₄ plants are divided into three subtypes on the basis of decarboxylating enzymes: NADP-malic enzyme (ME), NAD-ME and phosphoenolpyruvate carboxykinase. Although the M chloroplasts of all C₄ species are randomly distributed along the cell walls, BS chloroplasts are located either in a centripetal (close to the vascular tissue) or in a centrifugal (close to M cells) position, depending on the species (Fig. 1A).⁷ Thus, C₄ M and BS cells have different systems for chloroplast positioning: an M cell-specific system for dispersing chloroplasts and a BS cell-specific system for holding chloroplasts in a centripetal or centrifugal disposition.Open in a separate windowFigure 1The intracellular arrangement of chloroplasts in finger millet (Eleusine coracana), an NAD-ME-type C₄ plant. (A) Light micrograph of a transverse section of a leaf blade from a control plant. Bundle sheath (BS) cells surround the vascular tissues, while mesophyll (M) cells encircle the cylinders of the BS cells. BS chloroplasts are well developed, and are located in a centripetal position, whereas M chloroplasts are randomly distributed along the cell walls. B, bundle sheath cell; M, mesophyll cell; V, vascular bundle. (B) Transverse section of a leaf blade from a drought-stressed plant. Most M chloroplasts are aggregatively distributed toward the BS side, while the centripetal arrangement of BS chloroplasts is unchanged. (C and D) Transverse sections of leaf segments irradiated with blue light of intensity 500 µmol m⁻² s⁻¹ with or without 30 µM ABA for 8 h (C and D, respectively). The adaxial side of each leaf section (upper side in the photograph) was illuminated. In the absence of ABA, M chloroplasts exhibited avoidance movement on the illuminated side and aggregative movement on the opposite side. In the presence of ABA, aggregative movement was observed on both sides. Scale bars = 50 µm.     

Polarity of Production of Polyphenols and Development of Various Enzyme Activities in Cut-injured Sweet Potato Root Tissue

Investigation of polyphenol production in cut-injured sweet potato (Ipomoea batatas Lam. cv. Kokei 14) roots by histochemical and quantitative methods showed that polyphenols were produced in striking amounts in the proximal side of the tissue pieces (2 cm thick), but only in small amounts in cells of the distal side. In response to cut injury, formation of the enzymes related to polyphenol biosynthesis, phenylalanine ammonia-lyase and trans-cinnamic acid 4-hydroxylase, was also pronounced in the proximal side of the tissue pieces and slight in the distal side. The similar polarity was observed in the development of activities of various enzymes, such as NADPH-cytochrome c oxidoreductase, acid invertase, peroxidase, o-diphenol oxidase, and cytochrome c-O₂ oxidoreductase. Acropetal development of polyphenol contents and of various enzyme activities may be related to the acropetal movement of indoleacetic acid (IAA) in roots of various plants. Treatment of the distal surface of tissue pieces with IAA or 2,4-dichlorophenoxyacetic acid caused polyphenol production but treatment with gibberellic acid, abscisic acid, kinetin, or ethylene had little effect. The results suggest that IAA may play a role in the metabolic response to cut injury.     

The calcium content of the cellular slime mold, Dictyostelium discoideum, during development and differentiation

A high calcium concentration is known to induce stalk differentiation of the cellular slime mold D. discoideum. Therefore, the change in the calcium content of this organism during differentiation was studied and found to vary during development, more calcium being found in the anterior prestalk cells of the pseudoplasmodium (slug) than in the posterior prespore cells. It is concluded from the results that calcium is of importance in the cell differentiation of this organism and particularly in stalk formation.     

Adaptive Mechanisms in the compound eye of Squilla mantis (Crustacea,Stomatopoda)

Summary Light and dark adaptations were studied in the eye of Squilla mantis. Light adaptation is characterized by (1) a proximal shift of the distal pigment sheath (DPS) surrounding the proximal portion of the crystalline cone above its zone of contact with the rhabdom; (2) flattening of the distal pigment sheath; (3) lengthening of the crystalline cone correlated with shortening of the rhabdom; (4) a migration of screening pigment granules in retinula cells in the protoplasmic bridges crossing the perirhabdomal space. In animals kept in constant darkness, longitudinal displacements of the distal pigment sheath were found to be subject to a circadian rhythm characterized by a maximal light adaptation state at about 5 p.m. and a minimal one at 5 a.m. Screening pigment granule translocation in retinula cells does not show such rhythmic activity.Abbreviations a, b maximal incidence angles in L.A., and D.A., respectively - Cc crystalline cone - Dps distal pigment sheath - I extreme incident light beam - Prs perirhabdomal space - Rh rhabdom - Rp reflecting pigment This research has been supported by grant 3.012-76 of the Swiss National Science Foundation     

Rac1-Dependent Collective Cell Migration Is Required for Specification of the Anterior-Posterior Body Axis of the Mouse

Cell migration and cell rearrangements are critical for establishment of the body plan of vertebrate embryos. The first step in organization of the body plan of the mouse embryo, specification of the anterior-posterior body axis, depends on migration of the anterior visceral endoderm from the distal tip of the embryo to a more proximal region overlying the future head. The anterior visceral endoderm (AVE) is a cluster of extra-embryonic cells that secretes inhibitors of the Wnt and Nodal pathways to inhibit posterior development. Because Rac proteins are crucial regulators of cell migration and mouse Rac1 mutants die early in development, we tested whether Rac1 plays a role in AVE migration. Here we show that Rac1 mutant embryos fail to specify an anterior-posterior axis and, instead, express posterior markers in a ring around the embryonic circumference. Cells that express the molecular markers of the AVE are properly specified in Rac1 mutants but remain at the distal tip of the embryo at the time when migration should take place. Using tissue specific deletions, we show that Rac1 acts autonomously within the visceral endoderm to promote cell migration. High-resolution imaging shows that the leading wild-type AVE cells extend long lamellar protrusions that span several cell diameters and are polarized in the direction of cell movement. These projections are tipped by filopodia-like structures that appear to sample the environment. Wild-type AVE cells display hallmarks of collective cell migration: they retain tight and adherens junctions as they migrate and exchange neighbors within the plane of the visceral endoderm epithelium. Analysis of mutant embryos shows that Rac1 is not required for intercellular signaling, survival, proliferation, or adhesion in the visceral endoderm but is necessary for the ability of visceral endoderm cells to extend projections, change shape, and exchange neighbors. The data show that Rac1-mediated epithelial migration of the AVE is a crucial step in the establishment of the mammalian body plan and suggest that Rac1 is essential for collective migration in mammalian tissues.     

Fine structural description of the lateral ocellus of Craterostigmus tasmanianus Pocock, 1902 (Chilopoda: Craterostigmomorpha) and phylogenetic considerations

The lateral lens eye of adult Craterostigmus tasmanianus Pocock, 1902 (a centipede from Australia and New Zealand) was examined by light and electron microscopy. An elliptical, bipartite eye is located frontolaterally on either side of the head. The nearly circular posterior part of the eye is characterized by a plano-convex cornea, whereas no corneal elevation is visible in the crescentic anterior part. The so-called lateral ocellus appears cup-shaped in longitudinal section and includes a flattened corneal lens comprising a homogeneous and pigmentless epithelium of cornea-secreting cells. The retinula consists of two kinds of photoreceptive cells. The distribution of the distal retinula cells is highly irregular. Variable numbers of cells are grouped together in multilayered, thread-like unions extending from the ventral and dorsal margins into the center of the eye. Around their knob-like or bilobed apices the distal retinula cells give rise to fused polymorphic rhabdomeres. Both everse and inverse cells occur in the distal retinula. Smaller, club-shaped proximal retinula cells are present in the second (limited to the peripheral region) and proximal third of the eye, where they are arranged in dual cell units. In its apical region each unit produces a small, unidirectional rhabdom of interdigitating microvilli. All retinula cells are surrounded by numerous sheath cells. A thin basal lamina covers the whole eye cup, which, together with the distal part of the optic nerve, is wrapped by external pigment cells filled with granules of varying osmiophily. The eye of C. tasmanianus seemingly displays very high complexity compared to many other hitherto studied euarthropod eyes. Besides the complex arrangement of the entire retinula, the presence of a bipartite eye cup, intraocellar exocrine glands, inverse retinula cells, distal retinula cells with bilobed apices, separated pairs of proximal retinula cells, medio-retinal axon bundles, and the formation of a vertically partitioned, antler-like distal rhabdom represent apomorphies of the craterostigmomorph eye. These characters therefore collectively underline the separate position of the Craterostigmomorpha among pleurostigmophoran centipedes. The remaining retinal features of C. tasmanianus agree with those known from other chilopod eyes and, thus, may be considered plesiomorphies. Characters like the unicorneal eye cup, sheath cells, and proximal rhabdomeres with interdigitating microvilli were already present in the ground pattern of the Pleurostigmophora. Other retinal features were developed in the ancestral lineage of the Phylactometria (e.g., large elliptical eyes, external pigment cells, polygonal sculpturations on the corneal surface). The homology of all chilopod eyes (including Notostigmophora) is based principally on the possession of a dual type retinula.     

Development of the simple cellular slime mold Dictyostelium minutum

An ultrastructural study has been made of the life cycle of the cellular slime mold Dictyostelium minutum. The development of D. minutum is rather simple if compared with Dictyostelium discoideum. After 2 hr of starvation, amoebas move in a nonpulsatile manner towards an acrasin-secreting founder cell. The chemotactic signal is not relayed by the amoebas and stream formation toward primary aggregation centers does not occur. Usually, more than one fruiting body arises from one pseudoplasmodium. No migration of the pseudoplasmodium takes place. The first signs of spore differentiation are found in late aggregates, where prespore cells can be distinguished from the surrounding undifferentiated cells by the increased electron density of their cytoplasm. Vacuoles comparable with the prespore vacuole of D. discoideum appear in both cell types; they fuse with the plasma membrane during sporulation of electron-dense cells and are lysed in electron-light cells, which eventually form the stalk. In contrast with D. discoideum no spatial separation between prespore and prestalk cells is found until very late in fruiting body development.     

Flagellar Activity of the Colony Members of Volvox aureus Ehrbg. during Light Stimulation*

SYNOPSIS. The flagellar behavior of the colonial Volvox aureus Ehrbg. was examined by placing 1.01 μ polystyrene particles in suspension with Volvox, and recording particle movement photomicrographically. When directional light stimulation was given, flagellar activity ceased in the anterior cells of the stimulated side. Such responses create unequal driving forces on the 2 sides of the colony, so that the colony turns toward the stimulated side. Dose response studies indicated a photoresponse gradient from front to rear in the colony, anterior cells being most responsive. The mechanism of gradient formation has yet to be determined.     

Pigment migration in the compound eye of Manduca sexta: Effects of light,nitrogen and carbon dioxide

Migration of screening pigment granules was studied in the secondary pigment cells of the compound eye of the tobacco hornworm moth Manduca sexta. The granules aggregate at the distal ends of these elongate cells during dark-adaptation, and disperse proximally during light-adaptation, to provide a longitudinal pupil regulating the entrance of light into the eye. Pigment position was measured directly during the couse of migration in sectioned quick-frozen eyes, and the pupillary response was measured in the intact eyes of living moths by reflectance microscopy. The influences of nitrogen and carbon dioxide anaesthesia on pigment migration were investigated in the light of earlier studies on other speicies showing that hypoxia results in dispersal. In accordance with these previous studies, rapid dispersal results from nitrogen hypoxia in Manduca, the pigment spreading farther than it does in light-adaptation. By contrast, the pigment disperses only slightly in response to carbon dioxide hypoxia. Carbon dioxide also inhibits the rapid, extensive dispersal caused by light and nitrogen. Thus the pseudopupil of the eye remains dilated in carbon dioxide anaesthetized moths even under bright illumination. Light-induced dispersal is restored with the addition of oxygen to the carbon dioxide atmosphere. These results suggest, contrary to the conclusions of earlier studies, that pigment dispersal in light-adaptation requires metabolic energy. The inhibition of pigment migration by carbon dioxide is unlikely to be the result of hypoxia; we suggest that low cellular pH affects the mechanism of pigment-granule motility.     

Histology and regeneration of the radula of Pomacea bridgesi (Gastropoda,Prosobranchia)

Summary Histology, physiological regeneration, and degradation of the taenioglossan prosobranch radula and its concomitant epithelia were studied by light and electron microscopy (TEM, SEM), electron microprobe analysis, and autoradiography. Taenioglossa have seven multicellular odontoblastic cushions which produce the tooth matrix by apocrine secretion; many long microvilli are also incorporated. In contrast to pulmonates, the odontoblasts of prosobranchs are capable of division, and their mitoses contribute to the expansion of the cushions, but presumably also to the displacement of degenerating odontoblasts. The seven cushions are isolated from each other by separation cells. The radular membrane is produced from microvilli of membranoblasts and a substance secreted at the base of microvilli.Strands of the supraradular epithelium subsequently move in between the teeth and finally enclose them completely. They effect the hardening and mineralization of the teeth. The strands move together with the radula towards the anterior and are extruded at the opening of the radular sheath; their degeneration, however, has already started in the middle section of the sheath. Epithelial cells are produced by two completely separated mitotic centres which lie dorsolaterally at the end of the sheath.In the subradular epithelium, mitotic activity is scattered over the posterior half of the sheath but is not found in the region where the supramedian radula tensor muscle is inserted. The epithelial cells move forward, but at a much lower rate than the radula. At the opening of the sheath the subradular membrane is generated, while cells of the subradular epithelium lying between the lamellae of the subradular membrane are extruded.The subradular membrane is limited to the functional part of the radula. It is situated on the distal radular epithelium, which is obviously not a continuation of the subradular epithelium. In test animals treated with tritiated thymidine, there is a very strong stationary centre of labeled cells at the beginning of the epithelium, but so far no mitoses have been found in this centre and the labeled cells do not move on continually. In the middle of the distal epithelium mitoses do occur, and the labeled cells permit the assumption that these cells do not migrate at all to the anterior end. At least in Prosobranchia, the distal radular epithelium does not transport the radula to its degradation zone. The transport mechanism for the radula is still unknown.     

Regulation of the orientation movement of chloroplasts in epidermal cells of Vallisneria: cooperation of phytochrome with photosynthetic pigment under low-fluence-rate light

In epidermal cells of the leaves of the aquatic angiosperm Vallisneria gigantea Graebner, the chloroplasts accumulate in the outer periclinal layer of cytoplasm (P side) under light at low fluence rates. The nature of such intracellular orientation of chloroplasts was investigated in a semiquantitative manner. Time-lapse video microscopy revealed that, while irradiation with red light (650 nm, 0.41 W · m^–2) rapidly accelerated the migration of chloroplasts, not only from the anticlinal layers of cytoplasm (A sides) to the P side but also from the P side to the A sides, the increased rate of migration in both directions returned to the control rate upon subsequent irradiation with far-red light (746nm, 0.14W · m^–2). These effects of red and far-red light could be observed repeatedly, both in the presence and in the absence of inhibitors of photosynthesis, suggesting the involvement of phytochrome as the photoreceptor. After saturating irradiation with red light, the increased rate of migration of chloroplasts from the P side to the A sides declined more rapidly than the increased rate of migration in the opposite direction. This imbalance in the migration of chloroplasts between the two opposing directions resulted in the accumulation of chloroplasts on the P side. The more rapid decline in the rate of migration of chloroplasts from the P side to the A sides than in the opposite direction was not observed in the presence of an inhibitor of photosynthesis. It appears, therefore, that phytochrome and photosynthetic pigment cooperatively regulate the accumulation of chloroplasts on the P side through modulation of the nature of the movement of the chloroplasts.Abbreviations A side cytoplasmic layer that faces the anticlinal wall - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - Pfr farred-light-absorbing form of phytochrome - Pr red-light-absorbing form of phytochrome - P side cytoplasmic layer that faces the outer periclinal wall This work was supported in part by Grants-in-Aid from the Japanese Ministry of Education, Science and Culture to S.T. and R.N. The authors are indebted to the Osaka branch of Kashimura Inc. for their kind cooperation in preparing the GREEN software.     

The ultrastructure and development of the colonial sheath of Microcystis marginata

The colonial sheath of Microcystis marginata has a definite structure as seen by light and electron microscopy, consisting of a relatively smooth inner surface and densely packed, long fibrils on the outer surface. The sheath initially forms around the single cell and expands by continual deposition of sheath material to accomodate the synchronously dividing cells of the colony.     

Dynamic changes in the organization of microfilaments associated with the photocontrolled motility of chloroplasts in epidermal cells ofVattisneria

Summary Using time-lapse video microscopy, we performed a semiquantitative investigation of the movement of chloroplasts on the cytoplasmic layer that faces the outer periclinal wall (P side) of epidermal cells of leaves of the aquatic angiospermVallisneria gigantea Graebner. Under continuous irradiation with red light (650 nm, 0.41 W/m²), the movement of chloroplasts on the P side was transiently accelerated within 5 min. The increased movement began to decrease at around 20 min and fell below the original level after 40 to 60 min of irradiation with red light. The acceleration and deceleration of movement of chloroplasts on the P side seemed to lead directly to the increase and the subsequent decrease in the rate of migration of chloroplasts from the P side to the anticlinal layers of cytoplasm, which are responsible for the accumulation of chloroplasts on the P side, as we demonstrated previously. In the presence of inhibitors of photosynthesis, the accelerated movement of chloroplasts was maintained for as long as the chloroplasts were irradiated with red light. The rapid acceleration and deceleration of the movement of chloroplasts could be observed repeatedly with sequential irradiation with red and then far-red light (746 nm, 0.14 W/m²). Concomitantly with the loss of motility of chloroplasts on the P side, a dynamic change in the configuration of microfilaments, from a network to a honeycomb, occurred on the P side.Abbreviations APW artificial pond water - A side cytoplasmic layer that faces the anticlinal wall - ATP adenosine triphosphate - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - F-actin fibrous actin - FITC fluorescein isothiocyanate - PBS phosphate-buffered saline - Pfr farred-light-absorbing form of phytochrome - Pr red-light-absorbing form of phytochrome - P side cytoplasmic layer that faces the outer periclinal wall Dedicated to Professor Eldon H. Newcomb in recognition of his contributions to cell biology     

The avoidance and aggregative movements of mesophyll chloroplasts in C(4) monocots in response to blue light and abscisic acid

In C(4) plants, mesophyll (M) chloroplasts are randomly distributed along the cell walls, whereas bundle sheath chloroplasts are located in either a centripetal or centrifugal position. It was reported previously that only M chloroplasts aggregatively redistribute to the bundle sheath side in response to extremely strong light or environmental stresses. The aggregative movement of M chloroplasts is also induced in a light-dependent fashion upon incubation with abscisic acid (ABA). The involvement of reactive oxygen species (ROS) and red/blue light in the aggregative movement of M chloroplasts are examined here in two distinct subtypes of C(4) plants, finger millet and maize. Exogenously applied hydrogen peroxide or ROS scavengers could not change the response patterns of M chloroplast movement to light and ABA. Blue light irradiation essentially induced the rearrangement of M chloroplasts along the sides of anticlinal walls, parallel to the direction of the incident light, which is analogous to the avoidance movement of C(3) chloroplasts. In the presence of ABA, most of the M chloroplasts showed the aggregative movement in response to blue light but not red light. Together these results suggest that ROS are not involved in signal transduction for the aggregative movement, and ABA can shift the blue light-induced avoidance movement of C(4)-M chloroplasts to the aggregative movement.