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相关概念视频

Plasmodesmata02:32

Plasmodesmata

35.0K
The organs in a multicellular organism’s body are made up of tissues formed by cells. To work together cohesively, cells must communicate. One way that cells communicate is through direct contact with other cells. The points of contact that connect adjacent cells are called intercellular junctions.
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Plasmodesmata01:20

Plasmodesmata

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In a multicellular organism, cells must communicate to work together in a coordinated manner. One way that cells communicate is through direct contact with other cells. The points of contact that connect adjacent cells are called intercellular junctions.
Intercellular junctions are a feature of fungal, plant, and animal cells. However, different types of junctions are found in different kinds of cells. Intercellular junctions found in animal cells include tight junctions, gap junctions, and...
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Contact-dependent Signaling01:19

Contact-dependent Signaling

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Contact-dependent signaling, as the name suggests, requires that communicating cells be in direct contact with each other. This is achieved either through receptor-ligand interactions or by specialized cytoplasmic channels that allow the flow of small molecules between cells. In animal cells, channels called gap junctions facilitate contact-dependent signaling in certain tissues, whereas, plasmodesmata perform a similar function in plants.
Gap Junctions
In animal cells, gap junctions are formed...
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Tonicity in Plants00:53

Tonicity in Plants

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Tonicity describes the capacity of a cell to lose or gain water. It depends on the quantity of solute that does not penetrate the membrane. Tonicity delimits the magnitude and direction of osmosis and results in three possible scenarios that alter the volume of a cell: hypertonicity, hypotonicity, and isotonicity. Due to differences in structure and physiology, tonicity of plant cells is different from that of animal cells in some scenarios.
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Tonicity in Plants01:20

Tonicity in Plants

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Plant cells maintain appropriate osmotic balance in extreme conditions. For instance, plants in dry environments store water in vacuoles, limit the opening of their stoma, and have thick, waxy cuticles to prevent unnecessary water loss. Some species of plants that live in salty environments store salt in their roots. As a result, water osmosis occurs in the root from the surrounding soil.
Tonicity
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The Apoplast and Symplast01:46

The Apoplast and Symplast

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Plant growth depends on its ability to take up water and dissolved minerals from the soil. The root system of every plant is equipped with the necessary tissues to facilitate the entry of water and solutes. The plant tissues involved in the transport of water and minerals have two major compartments - the apoplast and the symplast. The apoplast includes everything outside the plasma membrane of living cells and consists of cell walls, extracellular spaces, xylem, phloem, and tracheids. The...
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Updated: Jan 14, 2026

A Strategy to Validate the Role of Callose-mediated Plasmodesmal Gating in the Tropic Response
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A Strategy to Validate the Role of Callose-mediated Plasmodesmal Gating in the Tropic Response

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塑体法规:上下文很重要

Leigh-Anne Worthington1, Jung-Youn Lee1

  • 1Department of Plant and Soil Sciences, University of Delaware, Newark, DE 19713, U. S. A.

Journal of experimental botany
|January 13, 2026
PubMed
概括
此摘要是机器生成的。

植物使用等离子体进行细胞通信,通过糖调节它们的开放. 这个过程是信号特异性的,通过共享的监管机制,通过共享的监管机制,导致多样化的生物结果,这是未来研究的关键领域.

关键词:
血体质量可能会发生.卡洛索斯,卡洛索斯,卡洛索斯.细胞信号传递是细胞的信号传递.细胞间的细胞间通信.发展发展发展发展发展.免疫力是一种免疫力.质体中存在的蛋白质.

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Identification of Plasmodesmal Localization Sequences in Proteins In Planta
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Identification of Plasmodesmal Localization Sequences in Proteins In Planta

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相关实验视频

Last Updated: Jan 14, 2026

A Strategy to Validate the Role of Callose-mediated Plasmodesmal Gating in the Tropic Response
12:18

A Strategy to Validate the Role of Callose-mediated Plasmodesmal Gating in the Tropic Response

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Author Spotlight: Microscopic Analysis of Protein Localization at Plasmodesmata in Plants
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Identification of Plasmodesmal Localization Sequences in Proteins In Planta
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Identification of Plasmodesmal Localization Sequences in Proteins In Planta

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科学领域:

  • 植物生物学 植物生物学
  • 细胞生物学 细胞生物学
  • 分子生物学分子生物学

背景情况:

  • 多细胞生命需要平衡细胞团结和自主性.
  • 植物利用等离子体,细胞质桥梁,进行细胞间通信.
  • 等离子体克服了细胞壁的限制,使局部和全身信号传递成为可能.

研究的目的:

  • 审查调节等离子体透性的分子机制.
  • 探索等离子体调节的上下文依赖性.
  • 讨论信号通路在控制等离子体中的整合.

主要方法:

  • 关于等离子体的最新科学文献的综述.
  • 分子参与者和调节复合体的分析.
  • 讨论信号网络及其整合.

主要成果:

  • 等离子体透性主要通过质的积累和降解来调节.
  • 糖调节是特定于信号的,并且在机制上有多样性.
  • 对共享的菌机制的融合调节创造了生物特异性.

结论:

  • 了解等离子体调节对于植物生物学至关重要.
  • 监管复杂的组装和信号集成是关键的研究前沿.
  • 不同的信号通路汇聚在上,以获得特定的生物结果.