Spindle orientation along the developmental axes in echinoderm embryos

棘皮动物胚胎沿发育轴的纺锤体方向

基本信息

批准号：
8733008
负责人：
Charles Bradley Shuster
金额：
$ 42.65万
依托单位：
NEW MEXICO STATE UNIVERSITY LAS CRUCES
依托单位国家：
美国
项目类别：
财政年份：
2014
资助国家：
美国
起止时间：
2014-08-15 至 2018-07-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8733008
关键词：
Ablation Animal Model Animals Apical Asses Biological Models Caenorhabditis elegans Cell Count Cell Nucleus Cell Polarity Cell Size Cell division Cells Centrosome Complex Cues Cytoskeleton Data Development Developmental Biology Drosophila genus Dynein ATPase Embryo Endomesoderm Event Exhibits Exposure to Fertilization Genetic Germ Layers Grant Image Institution Invertebrates Lead Life Microtubules Minority Mitosis Mitotic Spindle Apparatus Mitotic spindle Modeling Molecular Motor Nuclear Optics Organism Pattern Phase Play Population Positioning Attribute Publishing Radial Relative (related person)Research Role Sea Urchins Series Signal Pathway Solid Specific qualifier value Staging Starfish Stem cells Students System Testing base cell type cellular imaging combinatorial daughter cell egg embryo stage 2 insight migration neuroblast novel public health relevance segregation zygote

项目摘要

DESCRIPTION (provided by applicant): A common feature of animal development is that following fertilization, embryos undergo a species-specific, stereotypical pattern of cleavages that sequester developmental determinants into specific daughter cells. And while lineage tracing and cell ablation studies have firmly established the significance of these developmentally asymmetric cell divisions, study of the mechanisms that align the mitotic spindle relative to the developmental axes has been largely limited to a few model organisms. Sea urchins undergo radial cleavage, with each cleavage plane bisecting the plane of the previous division. By the end of the fourth division, factors associated with the vegetal cortex ar sequestered by asymmetric cell division into a population of cells that will in turn direct the formation of the endomesoderm. And despite the intense scrutiny placed on the developmental role of micromeres in sea urchins and asymmetric cell division in other systems, we understand little of the mechanisms that facilitate spindle positioning relative to the animal-vegetal axis during echinoderm development. In almost all cell types studied to date, the mitotic spindle obeys Hertwig's rule and aligns itself along the long axis of the cell, facilitated by cortical puling forces generated by the microtubule motor, dynein. This proposal seeks to understand how the mitotic spindle is positioned relative to developmental axes during the initial cleavages of the sea urchin embryo. We hypothesize that factors that define cell polarity in early blastomeres align the nucleus and its duplicated centrosomes prior to the onset of mitosis to influence spindle orientation during both symmetric and asymmetric cell division. To test this hypothesis, we will perform a series of live cell analyses in sea urchin and starfish embryos, whose complementary features will aid in defining what we believe is a highly conserved mechanism for spindle alignment in early embryos. The lines of experimentation that form the Specific Aims of this proposal will: 1) Define the role of the PAR complex in defining blastomere polarity and spindle orientation during early cleavage; and 2) Assess the role of polarity factors and Disheveled during micromere formation. Together, is anticipated that the these studies will lead to a mechanistic understanding of how polarity factors act to effect a highly stereotypical and precise pattern of cell divisions that will ultimately lead to axis determination and the specification of the germ layers on echinoderm embryos.

描述（由申请人提供）：动物发育的一个共同特征是受精后，胚胎经历物种特异性、刻板的分裂模式，将发育决定因素隔离到特定的子细胞中。虽然谱系追踪和细胞消融研究已经牢固地确立了这些发育不对称细胞分裂的重要性，但对有丝分裂纺锤体相对于发育轴对齐的机制的研究在很大程度上仅限于少数模型生物。海胆经历径向分裂，每个分裂平面平分前一个分裂的平面。在第四次分裂结束时，与植物皮层相关的因子通过不对称细胞分裂而被隔离成一群细胞，而这些细胞又将指导内中胚层的形成。尽管人们对海胆中微粒的发育作用和其他系统中的不对称细胞分裂进行了深入的研究，但我们对棘皮动物发育过程中促进纺锤体相对于动植物轴定位的机制知之甚少。在迄今为止研究的几乎所有细胞类型中，有丝分裂纺锤体遵循赫特维希规则，并在微管马达动力蛋白产生的皮质拉力的促进下沿着细胞的长轴排列。该提案旨在了解海胆胚胎初始分裂期间有丝分裂纺锤体相对于发育轴的定位。我们假设，在早期卵裂球中定义细胞极性的因素在有丝分裂开始之前使细胞核及其复制的中心体对齐，从而影响对称和不对称细胞分裂期间纺锤体的方向。为了检验这一假设，我们将对海胆和海星胚胎进行一系列活细胞分析，它们的互补特征将有助于定义我们认为的早期胚胎中纺锤体排列的高度保守机制。构成本提案具体目标的实验路线将： 1) 定义 PAR 复合体在定义早期卵裂期间卵裂球极性和纺锤体方向方面的作用； 2) 评估极性因素和蓬乱在微粒形成过程中的作用。总之，预计这些研究将导致对极性因子如何作用以影响高度刻板和精确的细胞分裂模式的机械理解，这将最终导致棘皮动物胚胎上胚层的轴确定和规范。