Ca2+ and Calmodulin Dynamics during Photopolarization in Fucus serratus Zygotes

The role of Ca2+ in zygote polarization in fucoid algae (Fucus, Ascophyllum, and Pelvetia species) zygote polarization is controversial. Using a local source of Fucus serratus, we established that zygotes form a polar axis relative to unilateral light (photopolarization) between 8 and 14 h after fertilization (AF), and become committed to this polarity at approximately 15 to 18 h AF. We investigated the role of Ca2+, calmodulin, and actin during photopolarization by simultaneously exposing F. serratus zygotes to polarizing light and various inhibitors. Neither removal of Ca2+ from the culture medium or high concentrations of EGTA and LaCl3 had any effect on photopolarization. Bepridil, 3,4,5-trimethoxybenzoic acid 8-(diethylamino) octyl ester, nifedipine, and verapamil, all of which block intracellular Ca2 release, reduced photopolarization from 75 to 30%. The calmodulin antagonists N-(6-aminohexyl)-5-chloro-L-naphthalenesulfonamide and trifluoperazine inhibited photopolarization in all zygotes, whereas N-(6-aminohexyl)-L-naphthalenesulfonamide had no effect. Cytochalasin B, cytochalasin D, and latrunculin B, all of which inhibit actin polymerization, had no effect on photopolarization, but arrested polar axis fixation. The role of calmodulin during polarization was investigated further. Calmodulin mRNA from the closely related brown alga Macrocystis pyrifera was cloned and the protein was expressed in bacteria. Photopolarization was enhanced following microinjections of this recombinant calmodulin into developing zygotes. Confocal imaging of fluorescein isothiocyanate-labeled recombinant calmodulin in photopolarized zygotes showed a homogenous signal distribution at 13 h AF, which localized to the presumptive rhizoid site at 15 h AF.     

Signaling mechanisms in the establishment of plant and fucoid algal polarity

The establishment of polarity is a fundamental property of most cells. In tip‐growing plant and in fucoid algal cells, polarization specifies a growth pole, the center of localized secretion of new plasma membrane and cell wall material, generating a protrusion with a dome‐shaped apex. Although much progress has been made concerning the cellular machinery required to execute tip growth, less is known regarding the signaling mechanisms involved in selecting the growth site and regulating vectorial cell division and expansion. Fucoid algal zygotes use extrinsic cues to orient their growth axes and are thus well‐suited for studies of de novo selection of an axis. This process has been investigated largely by both pharmacological and immuno‐localization studies. In tip growing plant cells, polarity is often predetermined, as in the formation of root hairs or moss protonema branches. More focus has been on genomic and genetic studies to reveal the molecules involved in expressing a growth axis. Here we review the common roles of the cytoskeleton and signal transduction pathways in the formation of a developmental axis in fucoid algal cells and the control of tip growth in higher plant cells. Mol. Reprod. Dev. 77: 751–758, 2010. © 2010 Wiley‐Liss, Inc.     

Photopolarization of the Fucus sp. Zygote by Blue Light Involves a Plasma Membrane Redox Chain

Zygotes of fucoid algae are photopolarized by unidirectional blue light (BL). Polar axes are formed, fixed, and expressed by germination of a rhizoid. Hexacyanoferrate(III) ions (HCF) specifically inhibit transduction of the BL signal. HCF reduction by Fucus sp. zygotes occurs on the outer surface of the plasma membrane at higher rates in BL than in dark. These observations suggest that BL signal transduction involves a redox chain in the plasma membrane. Low doses of HCF (<50 pmol cell-1) inhibit photopolarization but not germination, hence uncoupling both processes. Exposure during the photosensitive period to higher doses of HCF together with BL significantly inhibits germination. Further results suggest that BL transduction is dependent on photosynthetic products that could also interact with redox processes.     

Calcium and the photopolarization ofPelvetia zygotes

The initially apolar zygotes of the brown algae,Fucus andPelvetia, form their main axes during the hours following fertilization and each cell expresses its axis by germinating at one location. The germinating region is destined to become the rhizoid and the rest of the zygote gives rise to the thallus. In response to unilateral blue light, the zygotes organize their developmental axes so that the rhizoids emerge on the shaded side, away from the light source. In the research reported here, the signaltransduction elements involved in the photopolarization ofPelvetia fastigiata De Toni zygotes have been investigated. It was found that exposure of zygotes to 90or 150-min pulses of unilateral light in the absence of extracellular Ca²⁺ completely eliminated photopolarization; that is, the cells formed their rhizoid-thallus axes randomly with respect to the light direction, while controls similarly exposed to light in normal (10 mM) Ca²⁺ were well polarized. When the cells were incubated in Ca²⁺-free sea water for an hour before being given the light pulse (while still in Ca²⁺-free sea water), they exhibited an unusual negative polarization: they formed their rhizoids on the hemisphere nearer the light source. Organic and inorganic calcium-channel blockers reduced or abolished photopolarization when present during light pulses. Reducing external Ca²⁺ to one-tenth of normal has the paradoxical effect of increasing calcium influx intoPelvetia zygotes. When zygotes were given light pulses in reduced extracellular calcium, the degree of photopolarization was increased substantially. These data are consistent with the idea that the formation of an intracellular gradient of [Ca²⁺] is an essential part of the polarization process. The fungus-derived calmodulin antagonist, ophiobolin A, blocked or greatly delayed germination when present continuously at a concentration of 100–300 nM. However, when present at 300 nM during a brief light pulse, it markedly increased the sensitivity of the cells to light. These results suggest that calmodulin may be the mediator of intracellular [Ca²⁺] gradients in the photopolarization process.     

Cortical actin filaments form rapidly during photopolarization and are required for the development of calcium gradients in Pelvetia compressa zygotes

Previous research has shown that cortical gradients of cytosolic Ca(2+) are formed during the photopolarization of Pelvetia compressa zygotes, with elevated Ca(2+) on the shaded hemisphere that will become the site of rhizoid germination. We report here that the marine sponge toxin, latrunculin B, which blocks photopolarization at nanomolar concentrations, inhibited the formation of the light-driven Ca(2+) gradients. Using low concentrations of microinjected fluorescent phalloidin as a tracer for actin filaments, we found that exposure to light induced a striking increase in actin filaments in the cells as indicated by an increase in fluorescence. The increase was quantified in the cortex, where it was most apparent, and the fluorescence there was found to increase by about a factor of 3. This increase in cortical phalloidin fluorescence was inhibited by latrunculin B at the same concentration required to inhibit Ca(2+) gradient formation and photopolarization. The distribution of the increasing phalloidin fluorescence was uniform with respect to the developing rhizoid-thallus axis during the formation of the axis, and no intense patches of fluorescence were observed. After germination, fluorescence suggestive of an apical ring of actin filaments was seen near the rhizoid tip. Finally, inhibitor studies indicated that myosin may be involved in the photopolarization process.     

The influence of light on microtubule dynamics and alignment in the Arabidopsis hypocotyl

Light and dark have antagonistic effects on shoot elongation, but little is known about how these effects are translated into changes of shape. Here we provide genetic evidence that the light/gibberellin-signaling pathway affects the properties of microtubules required to reorient growth. To follow microtubule dynamics for hours without triggering photomorphogenic inhibition of growth, we used Arabidopsis thaliana light mutants in the gibberellic acid/DELLA pathway. Particle velocimetry was used to map the mass movement of microtubule plus ends, providing new insight into the way that microtubules switch between orthogonal axes upon the onset of growth. Longitudinal microtubules are known to signal growth cessation, but we observed that cells also self-organize a strikingly bipolarized longitudinal array before bursts of growth. This gives way to a radial microtubule star that, far from being a random array, seems to be a key transitional step to the transverse array, forecasting the faster elongation that follows. Computational modeling provides mechanistic insight into these transitions. In the faster-growing mutants, the microtubules were found to have faster polymerization rates and to undergo faster reorientations. This suggests a mechanism in which the light-signaling pathway modifies the dynamics of microtubules and their ability to switch between orthogonal axes.     

The involvement of Ca<Superscript>2+</Superscript> gradients,Ca<Superscript>2+</Superscript> fluxes,and CaM kinase II in polarization and germination of<Emphasis Type="Italic"> Silvetia compressa</Emphasis> zygotes

Previous work has shown that distinct Ca²⁺ gradients precede and predict the loci of germination of the zygotes of the brown alga, Silvetia compressa (J. Agardh) E. Serrão, T.O. Cho, S.M. Boo et Brawley, that are polarized by unilateral blue light. We show here that dark-grown S. compressa zygotes also form cytosolic Ca²⁺ gradients prior to germination and then germinate from the site of elevated Ca²⁺. In no case did germination occur without a prior formation of a Ca²⁺ gradient. Using the self-referencing Ca²⁺-selective probe, we measured highly localized influx of Ca²⁺ during photopolarization, indicating that extracellular stores supply at least some of the Ca²⁺ needed to construct a gradient. Finally, we find that germination was inhibited by a bath-applied inhibitor of calcium/calmodulin-dependent kinase II (CaM kinase II), KN-93 (but not by its inactive analog, KN-92), and by an injected inhibitory peptide for the kinase. KN-93 did not interfere with the photopolarization of the zygotes, consistent with the view that calmodulin is not involved in the initial response to light. The KN-93 results indicate that the requirement for active CaM kinase II for germination ends about 2 h before overt germination. We conclude that Ca²⁺ gradients, generated in part by localized calcium entry from the seawater, are an essential part of the process of polarity development and expression in these cells, regardless of the nature of the external cue that directs the orientation of the axis. Calmodulin and CaM kinase II are involved in interpreting (but not in establishing) the calcium gradient, allowing germination to occur at the site of elevated calcium, but CaM kinase II appears not to be involved in the initiation of germination.     

Protein and Ribonucleic Acid Synthesis During the Diploid Life Cycle of Allomyces arbuscula

The diploid life cycle of Allomyces arbuscula may be divided into four parts: spore induction, germination, vegetative growth, and mitosporangium formation. Spore induction, germination, and mitosporangium formation are insensitive to inhibition of actinomycin D, probably indicating that stable, pre-existing messenger ribonucleic acid (RNA) is responsible for these developmental events. Protein synthesis is necessary during the entire life cycle except for cyst formation. A system for obtaining synchronous germination of mitospores is described. During germination there is a characteristic increase in the rate of synthesis of RNA and protein although none of the other morphogenetic changes occurring during the life cycle are necessarily accompanied by an appreciable change in the rate of macromolecular synthesis.     

Interactions between auxin transport and the actin cytoskeleton in developmental polarity of Fucus distichus embryos in response to light and gravity

Land plants orient their growth relative to light and gravity through complex mechanisms that require auxin redistribution. Embryos of brown algae use similar environmental stimuli to orient their developmental polarity. These studies of the brown algae Fucus distichus examined whether auxin and auxin transport are also required during polarization in early embryos and to orient growth in already developed tissues. These embryos polarize with the gravity vector in the absence of a light cue. The auxin, indole-3-acetic acid (IAA), and auxin efflux inhibitors, such as naphthylphthalamic acid (NPA), reduced environmental polarization in response to gravity and light vectors. Young rhizoids are negatively phototropic, and NPA also inhibits rhizoid phototropism. The effect of IAA and NPA on gravity and photopolarization is maximal within 2.5 to 4.5 h after fertilization (AF). Over the first 6 h AF, auxin transport is relatively constant, suggesting that developmentally controlled sensitivity to auxin determines the narrow window during which NPA and IAA reduce environmental polarization. Actin patches were formed during the first hour AF and began to photolocalize within 3 h, coinciding with the time of NPA and IAA action. Treatment with NPA reduced the polar localization of actin patches but not patch formation. Latrunculin B prevented environmental polarization in a time frame that overlaps the formation of actin patches and IAA and NPA action. Latrunculin B also altered auxin transport. Together, these results indicate a role for auxin in the orientation of developmental polarity and suggest interactions between the actin cytoskeleton and auxin transport in F. distichus embryos.     

Cytoskeleton and morphogenesis in brown algae

BACKGROUND: Morphogenesis on a cellular level includes processes in which cytoskeleton and cell wall expansion are strongly involved. In brown algal zygotes, microtubules (MTs) and actin filaments (AFs) participate in polarity axis fixation, cell division and tip growth. Brown algal vegetative cells lack a cortical MT cytoskeleton, and are characterized by centriole-bearing centrosomes, which function as microtubule organizing centres. SCOPE: Extensive electron microscope and immunofluorescence studies of MT organization in different types of brown algal cells have shown that MTs constitute a major cytoskeletal component, indispensable for cell morphogenesis. Apart from participating in mitosis and cytokinesis, they are also involved in the expression and maintenance of polarity of particular cell types. Disruption of MTs after Nocodazole treatment inhibits cell growth, causing bulging and/or bending of apical cells, thickening of the tip cell wall, and affecting the nuclear positioning. Staining of F-actin using Rhodamine-Phalloidin, revealed a rich network consisting of perinuclear, endoplasmic and cortical AFs. AFs participate in mitosis by the organization of an F-actin spindle and in cytokinesis by an F-actin disc. They are also involved in the maintenance of polarity of apical cells, as well as in lateral branch initiation. The cortical system of AFs was found related to the orientation of cellulose microfibrils (MFs), and therefore to cell wall morphogenesis. This is expressed by the coincidence in the orientation between cortical AFs and the depositing MFs. Treatment with cytochalasin B inhibits mitosis and cytokinesis, as well as tip growth of apical cells, and causes abnormal deposition of MFs. CONCLUSIONS: Both the cytoskeletal elements studied so far, i.e. MTs and AFs are implicated in brown algal cell morphogenesis, expressed in their relationship with cell wall morphogenesis, polarization, spindle organization and cytokinetic mechanism. The novelty is the role of AFs and their possible co-operation with MTs.     

Spatial organization of centrosome-attached and free microtubules in 3T3 fibroblasts

The spatial organization of microtubules is crucial for different cellular processes. It is traditionally supposed that fibroblasts have radial microtubule arrays consisting of long microtubules that run from the centrosome. However, a detailed analysis of the microtubule array in the internal cytoplasm has never been performed. In the current study, we used laser photobleaching to analyze the spatial organization of microtubules in the internal cytoplasm of cultured 3T3 fibroblasts. Cells were injected with Cy-3-labeled tubulin, after which the growth of microtubules in the centrosome region and peripheral parts of cytoplasm was assayed in the bleached zone. In most cases, microtubule growth in the bleached zone occurred rectilinearly; at distances of up to 5 μm, microtubules seldom bend more than 10°–15°. We considered a growing fragment of the microtubule as a vector with the beginning at the point of occurrence and the end at the point where the growth terminated (or the end point after 30 s if microtubule persistent growth proceeded for longer). We defined the direction of microtubule growth in different parts of the cell using these vectors and measured the angle of their deviation from the vector of comparison. In the area of the centrosome, we directed a comparison vector inside the bleached zone from the centrosome to the beginning of the growing microtubule segment; in the lamella and trailing part of the fibroblast, we used the vector of comparison directed along the long axis of the cell from its geometrical center to periphery. The microtubules growing straight away from the centrosome grew along the cell radius. However, at a distance of 10 μm from the centrosome, radially growing microtubules comprised 40% of the overall number, while at a distance of 20 μm, they made up only 25%. The rest of the microtubules grew in different directions, with the preferred angle between their growth direction and cell radius equaling around 90 °. In the lamella and trailing part of the fibroblast, 80% of all microtubules grew along the long axis of the cell or at an angle of no more than 20 °; 10–15% of microtubules grew along axis of the cell but towards the centrosome. Thus, in 3T3 fibroblasts, the radial system of microtubules is perturbed starting at a distance of several microns from the centrosome. In the internal cytoplasm, the microtubule system is completely disordered and, in the stretched parts of the polarized cell (lamella, trailing edge), the microtubule system again becomes well organized; microtubules are preferentially oriented along the long axis of the cell. From the results obtained, we conclude that the orderliness of microtubules at the periphery of the fibroblast is not a consequence of their growth from the centrosome; rather, their orientation is preset by local factors.     

Plant Proteus: brown algal morphological plasticity and underlying developmental mechanisms

Brown algae are multicellular photosynthetic marine organisms, ubiquitous on rocky intertidal shores at cold and temperate latitudes. Nevertheless, little is known about many aspects of their biology, particularly their development. Given their phylogenetic distance (1.6 billion years) from other plant organisms (land plants, and green and red algae), brown algae harbor a high, as-yet undiscovered diversity of biological mechanisms governing their development. They also show great morphological plasticity, responding to specific environmental constraints, such as sea currents, reduced light availability, grazer attacks, desiccation and UV exposure. Here, we show that brown algal morphogenesis is rather simple and flexible, and review recent genomic data on the cellular and molecular mechanisms known to date that can possibly account for this developmental strategy.     

Regulation of developmental and environmental signaling by interaction between microtubules and membranes in plant cells

Cell division and expansion require the ordered arrangement of microtubules, which are subject to spatial and temporal modifications by developmental and environmental factors. Understanding how signals translate to changes in cortical microtubule organization is of fundamental importance. A defining feature of the cortical microtubule array is its association with the plasma membrane; modules of the plasma membrane are thought to play important roles in the mediation of microtubule organization. In this review, we highlight advances in research on the regulation of cortical microtubule organization by membrane-associated and membrane-tethered proteins and lipids in response to phytohormones and stress. The transmembrane kinase receptor Rho-like guanosine triphosphatase, phospholipase D, phosphatidic acid, and phosphoinositides are discussed with a focus on their roles in microtubule organization.     

Modulation of Phototropin Signalosome with Artificial Illumination Holds Great Potential in the Development of Climate-Smart Crops

Changes in environmental conditions like temperature and light critically influence crop production. To deal with these changes, plants possess various photoreceptors such as Phototropin (PHOT), Phytochrome (PHY), Cryptochrome (CRY), and UVR8 that work synergistically as sensor and stress sensing receptors to different external cues. PHOTs are capable of regulating several functions like growth and development, chloroplast relocation, thermomorphogenesis, metabolite accumulation, stomatal opening, and phototropism in plants. PHOT plays a pivotal role in overcoming the damage caused by excess light and other environmental stresses (heat, cold, and salinity) and biotic stress. The crosstalk between photoreceptors and phytohormones contributes to plant growth, seed germination, photo-protection, flowering, phototropism, and stomatal opening.Molecular genetic studies using gene targeting and synthetic biology approaches have revealed the potential role of different photoreceptor genes in the manipulation of various beneficial agronomic traits. Overexpression of PHOT2 in Fragaria ananassa leads to the increase in anthocyanin content in its leaves and fruits. Artificial illumination with blue light alone and in combination with red light influence the growth, yield, and secondary metabolite production in many plants, while in algal species, it affects growth, chlorophyll content, lipid production and also increases its bioremediation efficiency. Artificial illumination alters the morphological, developmental, and physiological characteristics of agronomic crops and algal species. This review focuses on PHOT modulated signalosome and artificial illumination-based photo-biotechnological approaches for the development of climate-smart crops.     

Regulation of microtubule dynamics in 3T3 fibroblasts by Rho family GTPases

To get insight into the action of Rho GTPases on the microtubule system we investigated the effects of Cdc42, Rac1, and RhoA on the dynamics of microtubules in Swiss 3T3 fibroblasts. In control cells microtubule ends were dynamic: plus ends frequently switched between growth, shortening and pauses; the growth phase predominated over shortening. Free minus ends of microtubules depolymerized rapidly and never grew. Free microtubules were short-lived, and the microtubule network was organized into a radial array. In serum-starved cells microtubule ends became more stable: although plus ends still transited between growth and shortening, polymerization and depolymerization excursions became shorter and balanced each other. Microtubule minus ends were also stabilized. Consequently lifespan of free microtubules increased and microtubule array changed its radial pattern into a random one. Activation of Cdc42 and Rac1 in serum-starved cells promoted dynamic behavior of microtubule plus and minus ends, while inhibition of these GTPases in serum-grown cells suppressed microtubule dynamics and mimicked all effects of serum starvation. Activation of RhoA in serum-grown cells had effects similar to Cdc42 /Rac1 inactivation: it suppressed the dynamics of plus and minus ends, reduced the length of growth and shrinking episodes, and disrupted the radial organization of microtubules. However, in contrast to Cdc42 and Rac1 inactivation, active RhoA had no effect on the balance between microtubule growth and shortening. We conclude that Cdc42 and Rac1 have similar stimulating effects on microtubule dynamics while RhoA acts in an opposite way.     

Asymmetric division in fucoid zygotes is positioned by telophase nuclei

The relative contributions of cell polarity and nuclear position in specifying the plane of asymmetric division in fucoid zygotes were investigated. In zygotes developing normally, telophase nuclei were positioned parallel to the polar growth axis, and the division plane bisected both axes. To assess division plane specification, the colinearity of the nuclear and growth axes was uncoupled by treatment with pharmacological agents. Spatial correlations between the growth axis, telophase nuclei, and the division plane were analyzed in the treated zygotes. In all cases, cytokinesis was oriented transverse to the telophase mitotic array and was less well aligned with the growth axis. Telophase nuclei also played a predominant role in positioning the division plane in polyspermic zygotes. Microtubules from the telophase nuclei interdigitated throughout the plane of subsequent cytokinesis, and we speculate that they specify the division plane. Morphological markers of the division plane were not observed before telophase; the earliest division marker detected was a plate of actin that assembled in the zone of microtubule overlap late in telophase. These findings are consistent with division plane specification at cytoplast boundaries.     

Quantitative analysis of microtubule orientation in interdigitated leaf pavement cells

Leaf pavement cells are shaped like a jigsaw puzzle in most dicotyledon species. Molecular genetic studies have identified several genes required for pavement cells morphogenesis and proposed that microtubules play crucial roles in the interdigitation of pavement cells. In this study, we performed quantitative analysis of cortical microtubule orientation in leaf pavement cells in Arabidopsis thaliana. We captured confocal images of cortical microtubules in cotyledon leaf epidermis expressing GFP-tubulinβ and quantitatively evaluated the microtubule orientations relative to the pavement cell growth axis using original image processing techniques. Our results showed that microtubules kept parallel orientations to the growth axis during pavement cell growth. In addition, we showed that immersion treatment of seed cotyledons in solutions containing tubulin polymerization and depolymerization inhibitors decreased pavement cell complexity. Treatment with oryzalin and colchicine inhibited the symmetric division of guard mother cells.     

Apical cells of brown algae with particular reference to Sphacelariales, Dictyotales and Fucales

Brown algae show a significant diversity in thallus forms, giving a great number of model systems for the study of many important morphogenetic mechanisms. Thallus growth in brown algae is diffuse, intercalary or apical. The latter takes place by means of one or more apical cells. Among the brown algal groups, Sphacelariales, Dictyotales and Fucales give the best examples of apical growth, and have been repeatedly used for the study of the morphogenetic role of apical cells. In Sphacelariales the apical cells appear strongly polarized, the polarity expressed also on the organization of the microtubule cytoskeleton. These cells show a type of growth that can be compared with tip growth of root hairs, moss protonemata, pollen tubes and fungal hyphae, and is called ‘tip-like growth’. The thallus of Dictyotales grows by the activity of one or more apical cells showing variable degree of polarity. These cells do not exhibit any type of apical growth. In Fucales the vegetative thallus develops by means of an active apical meristem, which includes a large apical cell. This cell does not show polar organization or apical growth. However, in germinating zygotes of Fucales a polar axis is established and during the first stages of development they show a typical tip growth. In the present paper, the available information on the structure and division pattern of apical cells is presented. Their morphogenetic role is discussed, in relation to polarity, cytoskeleton organization, and apical dominance.