Actin Localization during Fucus Embryogenesis

Embryogenesis in the Fucales serves as a model system for studying the acquisition of cellular and developmental polarity. Fertilized eggs bear no asymmetry, yet within 16 hours, a developmental axis is formed and the unicellular zygote germinates in accordance with this axis. Microfilaments (actin) play a crucial role in establishing the axis as evidenced by the inhibitory effects of cytochalasins on axis fixation. The cellular content of actin was determined by immunoblot, whereas the localization of F-actin was investigated using the fluorescent probe rhodamine phalloidin. Three isoforms of actin were detected in constant amounts at all developmental stages. Actin networks were found to be distributed uniformly in eggs and zygotes through the period of early zygote development when the polar axis was formed. However, as the polar axis became irreversibly fixed in space, actin was localized at the presumptive germination site by a cytochalasin-sensitive process. This correlation supports the proposal that actin networks play a critical role in axis fixation, and is consistent with our hypothesis that this process involves stabilization of membrane components by transmembrane bridges from the cell wall to the microfilament cytoskeleton.     

High Rates of Actin Filament Turnover in Budding Yeast and Roles for Actin in Establishment and Maintenance of Cell Polarity Revealed Using the Actin Inhibitor Latrunculin-A

We report that the actin assembly inhibitor latrunculin-A (LAT-A) causes complete disruption of the yeast actin cytoskeleton within 2–5 min, suggesting that although yeast are nonmotile, their actin filaments undergo rapid cycles of assembly and disassembly in vivo. Differences in the LAT-A sensitivities of strains carrying mutations in components of the actin cytoskeleton suggest that tropomyosin, fimbrin, capping protein, Sla2p, and Srv2p act to increase actin cytoskeleton stability, while End3p and Sla1p act to decrease stability. Identification of three LAT-A resistant actin mutants demonstrated that in vivo effects of LAT-A are due specifically to impairment of actin function and implicated a region on the three-dimensional actin structure as the LAT-A binding site.

LAT-A was used to determine which of 19 different proteins implicated in cell polarity development require actin to achieve polarized localization. Results show that at least two molecular pathways, one actindependent and the other actin-independent, underlie polarity development. The actin-dependent pathway localizes secretory vesicles and a putative vesicle docking complex to sites of cell surface growth, providing an explanation for the dependence of polarized cell surface growth on actin function. Unexpectedly, several proteins that function with actin during cell polarity development, including an unconventional myosin (Myo2p), calmodulin, and an actin-interacting protein (Bud6/Aip3p), achieved polarized localization by an actin-independent pathway, revealing interdependence among cell polarity pathways. Finally, transient actin depolymerization caused many cells to abandon one bud site or mating projection and to initiate growth at a second site. Thus, actin filaments are also required for maintenance of an axis of cell polarity.

     

细胞极性的形成

细胞的极性形成对细胞分化、发育及其功能的发挥起着举足轻重的作用。现就线虫受精卵、果蝇卵母细胞和哺乳动物上皮细胞三类细胞极性形成的特点和异同进行阐述,并探讨了近年来三类细胞极性形成的研究进展。     

细胞壁在细胞极性建立和胚胎发生中的作用

植物细胞壁是一个活性的动态结构,其结构层次与组分随着发育进程而发生变化,且广泛参与细胞的各项生命活动,特别是在参与细胞命运决定、充当细胞发育信使、调控植物胚胎早期极性建立以及模式建成等方面发挥重要作用。     

Polarity and apical dominance in Fucus vesiculosus

In Fucus vesiculosus L., culture experiments have illustrated that within 2 mm of the apical cell, the origin of new meristems is inhibited. Further behind the apex, the influence of apical dominance gradually diminishes and beyond about 2 cm its effect is negligible. Polarity, which is so marked in the young plant, is not obvious in older tissues. There is no morphological difference between the branches produced from both cut surfaces of a segment of thallus. But, particularly in young tissue, there is a greater potential for regeneration from what is morphologically the upper end of a segment.     

Specification and Establishment of Dorsal-Ventral Polarity in Eggs and Embryos of Xenopus laevis

Dorsal-ventral (D-V) polarization in Xenopus eggs and embryos is achieved by passing through a series of complicated phenomena such as initial specification of the polarity before first cleavage, establishment of polarity during cleavage stages resulting in an acquisition of a unique developmental capacity by each blastomere, regional differentiation of mesoderm, and finally neural induction by Spemann's organizer. In order to gain an insight into basic mechanisms which govern D-V polarization, experimental modifications or perturbations of the body axis of embryos, including physical or chemical treatments of eggs, altered orientation of eggs under the normal gravity, centrifugation, manipulation of blastomeres, cytoplasmic withdrawal, and bisection or partial ligation of fertilized eggs are reviewed: all data are consistent with the concept that a cytoplasmic activity which becomes localized in the dorsal side of the egg is responsible or indispensable for the establishment of the D-V axis. The cytoplasmic activity is tentatively called "anterodorsal structure-forming activity." A model which explains the specification, establishment, and realization of D-V polarity in Xenopus laevis is proposed.     

神经祖细胞不对称分裂中纺锤体取向与细胞皮层极性的偶联机制

神经祖细胞的不对称分裂是神经发生的必要环节.近年来关于不对称分裂的研究,为果蝇及哺乳动物中枢神经系统发育期间神经祖细胞的分化机制提供了新的理解.在这一分裂模式中,纺锤体作为细胞结构的支架,受到细胞皮层极性信号的引导而改变取向,保证底部细胞命运决定子(cell fate determinants)的不对称分配.G蛋白亚基、各种接头蛋白及微管相关蛋白组成极性蛋白复合体,在纺锤体取向改变中发挥了有序的调节作用.现在细胞和分子水平探讨不对称分裂纺锤体与细胞皮层极性偶联这一标志性事件.     

Widely Conserved Signaling Pathways in the Establishment of Cell Polarity

How are the asymmetric distributions of proteins, lipids, and RNAs established and maintained in various cell types? Studies from diverse organisms show that Par proteins, GTPases, kinases, and phosphoinositides participate in conserved signaling pathways to establish and maintain cell polarity.The asymmetric distribution of proteins, lipids, and RNAs is necessary for cell fate determination, differentiation, and specialized cell functions that underlie morphogenesis (St Johnston 2005; Gonczy 2008; Knoblich 2008; Macara and Mili 2008; Martin-Belmonte and Mostov 2008). A fundamental question is how this asymmetric distribution is established and maintained in different types of cells and tissues. The formation of a specialized apical surface on an epithelial cell seems quite different from the specification of axons versus dendrites in a neuron, or the asymmetric division of a nematode zygote. Yet, remarkably, a conserved molecular toolbox is used throughout the metazoa to establish and maintain cell polarity in these and many other contexts. This toolbox consists of proteins that are components of signal transduction pathways (Goldstein and Macara 2007; Assemat et al. 2008; Yamanaka and Ohno 2008). However, our understanding of these pathways, and their intersection with other signaling networks, remains incomplete. Moreover, the regulation and cross talk between the polarity proteins and other signaling components varies from one context to another, which complicates the task of dissecting polarity protein function. Nonetheless, rapid progress is being made in our understanding of polarity signaling, which is outlined in this article, with an emphasis on the Par proteins, because these proteins play major roles integrating diverse signals that regulate cell polarity (Fig. 1) (see Munro and Bowerman 2009; Prehoda 2009; Nelson 2009).Open in a separate windowFigure 1.An overview of Par complex signaling, showing inputs (bottom) and outputs (top) with cellular functions that are targeted by these pathways (italics).     

Establishment and Maintenance of Cell Polarity During Leukocyte Chemotaxis

The term polarity refers to the differential distribution of the macromolecular elements of a cell, resulting in its asymmetry in function, shape and/or content. Polarity is a fundamental property of all metazoan cells in at least some stages, and is pivotal to processes such as epithelial differentiation (apical/basal polarity), coordinated cell activity within the plane of a tissue (planar cell polarity), asymmetric cell division, and cell migration. In the last case, an apparently symmetric cell responds to directional cues provided by chemoattractants, creating a polarity axis that runs from the cell anterior, or leading edge, in which actin polymerization takes place, to the cell posterior (termed uropod in leukocytes), in which acto-myosin contraction occurs. Here we will review some of the molecular mechansisms through which chemoattractants break cell symmetry to trigger directed migration, focusing on cells of the immune system. We briefly highlight some common or apparently contradictory pathways reported as important for polarity in other cells, as this suggests conserved or cell type-specific mechanisms in eukaryotic cell chemotaxis.     

Establishment and Maintenance of Cell Polarity During Leukocyte Chemotaxis

The term polarity refers to the differential distribution of the macromolecular elements of a cell, resulting in its asymmetry in function, shape and/or content. Polarity is a fundamental property of all metazoan cells in at least some stages, and is pivotal to processes such as epithelial differentiation (apical/basal polarity), coordinated cell activity within the plane of a tissue (planar cell polarity), asymmetric cell division, and cell migration. In the last case, an apparently symmetric cell responds to directional cues provided by chemoattractants, creating a polarity axis that runs from the cell anterior, or leading edge, in which actin polymerization takes place, to the cell posterior (termed uropod in leukocytes), in which acto-myosin contraction occurs. Here we will review some of the molecular mechanisms through which chemoattractants break cell symmetry to trigger directed migration, focusing on cells of the immune system. We briefly highlight some common or apparently contradictory pathways reported as important for polarity in other cells, as this suggests conserved or cell type-specific mechanisms in eukaryotic cell chemotaxis.Key Words: chemotaxis, polarization, lipid rafts, signaling, cytoskeleton     

非典型蛋白激酶C复合物在细胞极性建立中的作用

极性是多数细胞的共同特征,是细胞分化和细胞行使正常功能的基础,细胞极性的建立对于生物体的生长发育至关重要。过去十年的研究显示,进化上保守的非典型蛋白激酶C(aPKC)复合物在许多生物的多种细胞中都参与了细胞极性的建立,并且在其中扮演着相当重要的角色,这为揭示极性建立的机制提供了重要的线索。以线虫合子前-后极(anterior-posterior)的形成、哺乳动物和果蝇上皮细胞顶-底极(apical-basal)的建立以及果蝇神经母细胞不对称分裂中细胞命运决定子的分配这3个典型的极性过程为主线,综述了aPKC复合物在细胞极性建立中的作用,并探讨其中的分子机制。     

Isolation of Polysaccharides Sulfated during Early Embryogenesis in Fucus

Beginning 10 hours after fertilization, zygotes of Fucus distichus L. Powell incorporate (35)S into polysaccharides as a sulfate ester of fucose. These sulfated polysaccharides are sequestered in only the rhizoid cell of the two-celled embryo and can serve as a marker of cellular differentiation. Zygotes were pulsed at different times after fertilization with Na(2) (35)SO(4) to identify and isolate the fucans localized within the region of cytoplasm destined to become the rhizoid cell. Low molecular weight pools of (35)S were saturated within 60 minutes, with the greatest incorporation into ethanol-soluble and insoluble fractions occurring with 0.1 mm Na(2)SO(4) in the artificial sea water medium. At the time of rhizoid formation, four fucose-containing polysaccharide fractions incorporated (35)S. When each fraction was subjected to diethylaminoethyl chromatography, two components were eluted with KCl that contained over 84% of the fucose and 93% of the (35)S of the particular fraction. Highvoltage paper electrophoresis of each fraction also resulted in the separation of these two major components. Both components from each of the four fractions behaved identically when separated by diethylaminoethyl chromatography and paper electrophoresis. By comparing the incorporation of (35)S into the polysaccharide fractions at 4 and 16 hours after fertilization, the fucan-sulfate components that are localized in the cytoplasm at the time of rhizoid formation were isolated. Although sulfated polysaccharides in brown algae are reported to be very heterogeneous in terms of their sugar composition and complexes with other heteropolymers, we propose that there are two major components that are sulfated during early embryogenesis in Fucus. The location of these two sulfated polysaccharides in different chemical fractions may reflect their subcellular localization (e.g., cytoplasmic vesicles or cell walls), or their association with other heteropolymers.     

Asymmetric Localization of Cdx2 mRNA during the First Cell-Fate Decision in Early Mouse Development

1. Download : Download full-size image

Highlights? Cdx2 mRNA localizes apically upon embryo compaction at the eight-cell stage ? Cdx2 mRNA is inherited asymmetrically during asymmetric divisions ? Localization requires cell polarization and intact cytoskeletal components ? Mislocalization of Cdx2 mRNA decreases the number of pluripotent cells     

Planar Cell Polarity Enables Posterior Localization of Nodal Cilia and Left-Right Axis Determination during Mouse and Xenopus Embryogenesis

Left-right asymmetry in vertebrates is initiated in an early embryonic structure called the ventral node in human and mouse, and the gastrocoel roof plate (GRP) in the frog. Within these structures, each epithelial cell bears a single motile cilium, and the concerted beating of these cilia produces a leftward fluid flow that is required to initiate left-right asymmetric gene expression. The leftward fluid flow is thought to result from the posterior tilt of the cilia, which protrude from near the posterior portion of each cell''s apical surface. The cells, therefore, display a morphological planar polarization. Planar cell polarity (PCP) is manifested as the coordinated, polarized orientation of cells within epithelial sheets, or as directional cell migration and intercalation during convergent extension. A set of evolutionarily conserved proteins regulates PCP. Here, we provide evidence that vertebrate PCP proteins regulate planar polarity in the mouse ventral node and in the Xenopus gastrocoel roof plate. Asymmetric anterior localization of VANGL1 and PRICKLE2 (PK2) in mouse ventral node cells indicates that these cells are planar polarized by a conserved molecular mechanism. A weakly penetrant Vangl1 mutant phenotype suggests that compromised Vangl1 function may be associated with left-right laterality defects. Stronger functional evidence comes from the Xenopus GRP, where we show that perturbation of VANGL2 protein function disrupts the posterior localization of motile cilia that is required for leftward fluid flow, and causes aberrant expression of the left side-specific gene Nodal. The observation of anterior-posterior PCP in the mouse and in Xenopus embryonic organizers reflects a strong evolutionary conservation of this mechanism that is important for body plan determination.     

Role of Auxin in Induction of Polarity in Fucus vesiculosus Zygotes

We studied the effects of auxin (indole-3-acetic acid) on formation of the primary polarity axis in zygotes of the brown algae Fucus vesiculosusL. Within the first 2.5 h after fertilization, the zygotes release this phytohormone in the ambient medium. The treatment of developing zygotes with the inhibitor of indole-3-acetic acid transport from the cell 2,3,5-triiodobenzoic acid at 5 mg/l arrests the auxin secretion and leads to its accumulation in the cells. This causes a significant delay in zygote polarization. The treatment of zygotes with the exogenous indole-3-acetic acid at 1 mg/l stimulates cell polarization and formation of a rhizoid protuberance. When auxin was added to the medium with triiodobenzoic acid, the inhibitory effect of the latter was eliminated. It has been proposed that the content of indole-3-acetic acid in the ambient medium is a key factor in the induction of polarity of the F. vesiculosus zygotes.     

Factors Affecting Daughter Cells' Arrangement during the Early Bacterial Divisions

On agar plates, daughter cells of Escherichia coli mutually slide and align side-by-side in parallel during the first round of binary fission. This phenomenon has been previously attributed to an elastic material that restricts apparently separated bacteria from being in string. We hypothesize that the interaction between bacteria and the underneath substratum may affect the arrangement of the daughter bacteria. To test this hypothesis, bacterial division on hyaluronic acid (HA) gel, as an alternative substratum, was examined. Consistent with our proposition, the HA gel differs from agar by suppressing the typical side-by-side alignments to a rare population. Examination of bacterial surface molecules that may contribute to the daughter cells'' arrangement yielded an observation that, with disrupted lpp, the E. coli daughter cells increasingly formed non-typical patterns, i.e. neither sliding side-by-side in parallel nor forming elongated strings. Therefore, our results suggest strongly that the early cell patterning is affected by multiple interaction factors. With oscillatory optical tweezers, we further demonstrated that the interaction force decreased in bacteria without Lpp, a result substantiating our notion that the side-by-side sliding phenomenon directly reflects the strength of in-situ interaction between bacteria and substratum.     

Maternal mRNA and early development in Fucus serratus

Intact total and polyadenylated RNA have been isolated from unfertilized eggs of the brown marine macroalga Fucus serratus. The presence of functional messenger RNA has been demonstrated by translation in vitro. The major in-vitro translation product has an apparent molecular mass of 42 kDa. Immunoprecipitation of translation products of egg RNA using an anti-actin antibody yields a polypeptide which co-migrates with this major translation product.     

Changes in Oscillatory Dynamics in the Cell Cycle of Early Xenopus laevis Embryos

During the early development of Xenopus laevis embryos, the first mitotic cell cycle is long (∼85 min) and the subsequent 11 cycles are short (∼30 min) and clock-like. Here we address the question of how the Cdk1 cell cycle oscillator changes between these two modes of operation. We found that the change can be attributed to an alteration in the balance between Wee1/Myt1 and Cdc25. The change in balance converts a circuit that acts like a positive-plus-negative feedback oscillator, with spikes of Cdk1 activation, to one that acts like a negative-feedback-only oscillator, with a shorter period and smoothly varying Cdk1 activity. Shortening the first cycle, by treating embryos with the Wee1A/Myt1 inhibitor PD0166285, resulted in a dramatic reduction in embryo viability, and restoring the length of the first cycle in inhibitor-treated embryos with low doses of cycloheximide partially rescued viability. Computations with an experimentally parameterized mathematical model show that modest changes in the Wee1/Cdc25 ratio can account for the observed qualitative changes in the cell cycle. The high ratio in the first cycle allows the period to be long and tunable, and decreasing the ratio in the subsequent cycles allows the oscillator to run at a maximal speed. Thus, the embryo rewires its feedback regulation to meet two different developmental requirements during early development.     

Live Imaging of Cell Motility and Actin Cytoskeleton of Individual Neurons and Neural Crest Cells in Zebrafish Embryos

The zebrafish is an ideal model for imaging cell behaviors during development in vivo. Zebrafish embryos are externally fertilized and thus easily accessible at all stages of development. Moreover, their optical clarity allows high resolution imaging of cell and molecular dynamics in the natural environment of the intact embryo. We are using a live imaging approach to analyze cell behaviors during neural crest cell migration and the outgrowth and guidance of neuronal axons.Live imaging is particularly useful for understanding mechanisms that regulate cell motility processes. To visualize details of cell motility, such as protrusive activity and molecular dynamics, it is advantageous to label individual cells. In zebrafish, plasmid DNA injection yields a transient mosaic expression pattern and offers distinct benefits over other cell labeling methods. For example, transgenic lines often label entire cell populations and thus may obscure visualization of the fine protrusions (or changes in molecular distribution) in a single cell. In addition, injection of DNA at the one-cell stage is less invasive and more precise than dye injections at later stages.Here we describe a method for labeling individual developing neurons or neural crest cells and imaging their behavior in vivo. We inject plasmid DNA into 1-cell stage embryos, which results in mosaic transgene expression. The vectors contain cell-specific promoters that drive expression of a gene of interest in a subset of sensory neurons or neural crest cells. We provide examples of cells labeled with membrane targeted GFP or with a biosensor probe that allows visualization of F-actin in living cells¹.Erica Andersen, Namrata Asuri, and Matthew Clay contributed equally to this work.Open in a separate windowClick here to view.^{(58M, flv)}