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相关概念视频

Fruit Development, Structure, and Function01:58

Fruit Development, Structure, and Function

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Fruits form from a mature flower ovary. As seeds develop from the ovules contained within, the ovary wall undergoes a series of complex changes to form fruit. In some fruits, such as soybeans, the ovary wall dries; in other fruits, such as grapes, it remains fleshy. In some cases, organs other than the ovary contribute to fruit formation; such fruits are called accessory fruits.
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Pollination and Flower Structure02:40

Pollination and Flower Structure

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Flowers are the reproductive, seed-producing structures of angiosperms. Typically, flowers consist of sepals, petals, stamens, and carpels. Sepals and petals are the vegetative flower organs. Stamens and carpels are the reproductive organs.  
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Seed Structure and Early Development of the Sporophyte02:33

Seed Structure and Early Development of the Sporophyte

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Seed structures are composed of a protective seed coat surrounding a plant embryo, and a food store for the developing embryo. The embryo contains the precursor tissues for leaves, stem, and roots. The endosperm and cotyledons—seed leaves—act as the food reserves for the growing embryo.
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Exocytosis00:50

Exocytosis

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Exocytosis is a process that releases molecules outside the cell. Like other bulk transport mechanisms, exocytosis requires energy.
Exocytosis is the opposite of endocytosis, which brings molecules inside the cell. Sometimes, the released materials are signaling molecules. For example, neurons typically use exocytosis to release neurotransmitters. Cells also use exocytosis to insert proteins such as ion channels into their cell membranes, secrete proteins for use in the extracellular matrix, or...
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The Angiosperm Life Cycle02:39

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Plants have a life cycle split between two multicellular stages: a haploid stage—with cells containing one set of chromosomes—and a diploid stage—with cells containing two sets of chromosomes. The haploid stage is the gamete-producing gametophyte, and the diploid stage is the spore-producing sporophyte.
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Morphogenesis02:19

Morphogenesis

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Plant morphogenesis—the development of a plant’s form and structure—involves several overlapping developmental processes, including growth and cell differentiation. Precursor cells differentiate into specific cell types, which are organized into the tissues and organ systems that make up the functional plant.
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相关实验视频

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Fruit Volatile Analysis Using an Electronic Nose
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制造爆炸:爆炸性水果的形式和功能

Erin Cullen1, Angela Hay1

  • 1Department of Comparative Development and Genetics, Max Planck Institute for Plant Breeding Research, Carl-von-Linné-Weg 10, 50829 Cologne, Germany.

Current opinion in plant biology
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概括
此摘要是机器生成的。

种子的分散机制是多样化的,爆炸性果实利用局部的木质素和微管体生长来发射种子. 对卡尔达米因hirsuta等物种的比较研究揭示了超越模型生物的遗传洞察力.

关键词:
卡尔达明 hirsuta 的使用情况皮层微管是指皮层中的微管.爆炸性的种子分散.水果的发展水果的发展增长的增长 增长的增长在Lignin的基础上.

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Sexual Development and Ascospore Discharge in Fusarium graminearum
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相关实验视频

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科学领域:

  • 植物生物学 植物生物学
  • 发育遗传学的发展遗传学.
  • 进化植物学的植物学.

背景情况:

  • 种子散布适应性广泛存在,但在大多数物种中没有得到充分的研究.
  • 像阿拉比多普西斯这样的模型生物主要提供了对果实消亡机制的洞察.
  • 不同种子散布策略的遗传基础,特别是爆炸性散布,仍然在很大程度上是未知的.

研究的目的:

  • 调查爆炸性种子分散的遗传和发育基础.
  • 通过使用比较方法,扩大种子分散的研究范围,超越模型生物.
  • 为了确定驱动爆炸性果实进化的关键创新.

主要方法:

  • 使用诸如Cardamine hirsuta.等物种的比较发育遗传学.
  • 分析局部化的红素沉积模式.
  • 对果中微管体依赖生长的研究.

主要成果:

  • 爆炸性分散依赖于局部化的红素沉积和特定的微管子生长模式.
  • 果结构对爆炸物分散的危险性不如以前认为的.
  • 在Cardamine hirsuta的比较研究提供了新的遗传见解.

结论:

  • 爆炸性种子分散的关键创新与细胞壁修饰和生长模式有关.
  • 在非模型物种中开发实验工具对于理解种子分散多样性至关重要.
  • 这项研究扩大了我们对植物繁殖策略和进化的理解.