Jove
Visualize
联系我们
JoVE
x logofacebook logolinkedin logoyoutube logo
关于 JoVE
概览领导团队博客JoVE 帮助中心
作者
出版流程编辑委员会范围与政策同行评审常见问题投稿
图书馆员
用户评价订阅访问资源图书馆顾问委员会常见问题
研究
JoVE JournalMethods CollectionsJoVE Encyclopedia of Experiments存档
教育
JoVE CoreJoVE BusinessJoVE Science EducationJoVE Lab Manual教师资源中心教师网站
使用条款与条件
隐私政策
政策

相关概念视频

Mechanism of Filopodia Formation01:39

Mechanism of Filopodia Formation

3.0K
Filopodia are thin, actin-rich cellular protrusions that play an important role in many fundamental cellular functions. They vary in their occurrence, length, and positioning in different cell types, suggesting their diverse roles.
Their main function is to guide migrating cells during normal tissue morphogenesis or cancer metastasis by recognizing and making initial contacts with the extracellular matrix. However, they can also act as stationary cell anchors or help to establish communication...
3.0K
The Movement of Organelles and Vesicles01:43

The Movement of Organelles and Vesicles

6.0K
In eukaryotic cells,  cytoskeletal filaments such as actin, microtubules, and intermediate filaments form a mesh-like cytoskeletal network. These filaments serve as tracks for transporting cellular cargo. Specialized motor proteins use the chemical energy stored in adenosine triphosphate (ATP) for this transport. During interphase, microtubules are polarized, with the plus-end towards the cell periphery and the minus-end towards the cell center. Two microtubule-associated motor proteins,...
6.0K
Pinching-off of Coated Vesicles01:32

Pinching-off of Coated Vesicles

4.0K
Vesicle budding is orchestrated by distinct cytosolic proteins such as adaptor proteins, coat proteins, and GTPases. To initiate vesicle budding, membrane-bending proteins containing crescent-shaped BAR domains bind to the lipid heads in the bilayer and distort the membrane to form a protein-coated vesicle bud. Adaptors proteins such as AP2 for clathrin-coated vesicles can nucleate on the deformed membrane. Finally, coat proteins such as clathrin or COPI and COPII assemble into a coat forming...
4.0K
Mechanism of Lamellipodia Formation01:31

Mechanism of Lamellipodia Formation

3.5K
Cells migrating in response to external stimuli form lamellipodia, which are thin membrane protrusions supported by a mesh of linked, branched, or unbranched actin filaments. These actin filaments interact with myosin motor proteins, creating the dynamic actomyosin complex within the cytoskeleton. Contractility, or the ability to generate contractile stress, is inherent to the actomyosin complex. It helps cells detect the stiffness of the surrounding ECM and exert contractile force for...
3.5K
Vesicular Tubular Clusters01:45

Vesicular Tubular Clusters

3.0K
After budding out from the ER membrane, some COPII vesicles lose their coat and fuse with one another to form larger vesicles and interconnected tubules called vesicular tubular clusters or VTCs. These clusters constitute a compartment at the ER-Golgi interface known as ERGIC (Endoplasmic Reticulum Golgi Intermediate Compartment). The ERGIC is a mobile membrane-bound cargo transport system that sorts proteins secreted from ER and delivers them to the Golgi.
With the help of motor proteins such...
3.0K
Fusion of Secretory Vesicles with the Plasma Membrane01:26

Fusion of Secretory Vesicles with the Plasma Membrane

16.5K
Proteins and neurotransmitters in secretory vesicles can be released from a cell upon vesicle docking, priming, and fusion with the plasma membrane. Vesicles are docked and primed in preparation for the quick exocytosis of their contents in response to a stimulus. The fusion process is mainly carried out by a SNAP Receptor or SNARE complex, consisting of synaptobrevin, syntaxin-1, and SNAP-25.
In 1993, Jim Rothman proposed that the antiparallel pairing of vesicular and transmembrane SNAREs, or...
16.5K

您也可能阅读

相关文章

通过共同作者、期刊和引用图与本文相关的文章。

排序
Same author

Beyond unit cells: Programmable morphogenetic design of irregular architected materials.

Proceedings of the National Academy of Sciences of the United States of America·2026
Same author

Optical cooling by interfacial charge transfer in 2D heterostructures.

Nature·2026
Same author

Ion-shielding ultrathin encapsulation with hot-press bonded interface enables chronic stretchable bioelectronics.

Science advances·2026
Same author

Strong and brittle lithium dendrites.

Science (New York, N.Y.)·2026
Same author

A structural disorder function linking local symmetry breaking to plastic indicators and strength in amorphous solids.

Proceedings of the National Academy of Sciences of the United States of America·2026
Same author

Nanoporosity-driven deformation of additively manufactured nano-architected metals.

Nature communications·2026
Same journal

Demonstration of a quantum C-NOT gate in a time-multiplexed fully reconfigurable photonic processor.

Nature communications·2026
Same journal

Nonlinear quantum light source with van der Waals ferroelectric NbOX<sub>2</sub> (X = Br, I).

Nature communications·2026
Same journal

Antagonistic histone H2A variants and autonomous heterochromatin formation shape epigenomic patterns in Arabidopsis.

Nature communications·2026
Same journal

The long tail of nitrate pollution in groundwater challenges governance of global water quality.

Nature communications·2026
Same journal

Select microbial metabolites promote tau aggregation in a murine tauopathy model.

Nature communications·2026
Same journal

Warming climate has lengthened global intense tropical cyclone seasons.

Nature communications·2026
查看所有相关文章

相关实验视频

Updated: Jan 9, 2026

Membrane Remodeling of Giant Vesicles in Response to Localized Calcium Ion Gradients
08:15

Membrane Remodeling of Giant Vesicles in Response to Localized Calcium Ion Gradients

Published on: July 16, 2018

8.3K

相互作用的细丝驱动囊泡形态发生.

Chengyao Zhang1, Guijin Zou2, Yaxin Fang1

  • 1School of Mechanics and Engineering Science, Peking University, Beijing, China.

Nature communications
|December 6, 2025
PubMed
概括
此摘要是机器生成的。

囊泡内部相互作用的丝环驱动着各种形状的变化. 导线相互作用主导了囊泡形态,为软机器人和人工细胞提供了设计原则.

更多相关视频

In Vitro Reconstitution of the Actin Cytoskeleton Inside Giant Unilamellar Vesicles
10:19

In Vitro Reconstitution of the Actin Cytoskeleton Inside Giant Unilamellar Vesicles

Published on: August 25, 2022

4.1K
Rapid Encapsulation of Reconstituted Cytoskeleton Inside Giant Unilamellar Vesicles
07:48

Rapid Encapsulation of Reconstituted Cytoskeleton Inside Giant Unilamellar Vesicles

Published on: November 10, 2021

4.8K

相关实验视频

Last Updated: Jan 9, 2026

Membrane Remodeling of Giant Vesicles in Response to Localized Calcium Ion Gradients
08:15

Membrane Remodeling of Giant Vesicles in Response to Localized Calcium Ion Gradients

Published on: July 16, 2018

8.3K
In Vitro Reconstitution of the Actin Cytoskeleton Inside Giant Unilamellar Vesicles
10:19

In Vitro Reconstitution of the Actin Cytoskeleton Inside Giant Unilamellar Vesicles

Published on: August 25, 2022

4.1K
Rapid Encapsulation of Reconstituted Cytoskeleton Inside Giant Unilamellar Vesicles
07:48

Rapid Encapsulation of Reconstituted Cytoskeleton Inside Giant Unilamellar Vesicles

Published on: November 10, 2021

4.8K

科学领域:

  • 物理,软物质 物理,软物质
  • 生物物理学的生物物理.
  • 机器人技术 机器人技术 机器人技术

背景情况:

  • 囊泡和封闭的纤维之间的相互作用对于细胞过程如形态发生和运动性至关重要.
  • 线程可以作为通过工程互动调节系统行为的主动元素.

研究的目的:

  • 研究囊泡内相互作用的光线环如何诱导形态变化.
  • 了解纤维膜间和纤维膜内相互作用在囊泡和纤维膜变形中的作用.

主要方法:

  • 理论建模理论建模
  • 分子动力学模拟的模拟.

主要成果:

  • 观察到由丝相互作用驱动的各种系统范围的形态变化.
  • 识别了诸如线曲,重定向,囊泡拉伸和形状转变等现象.
  • 构建了在不同透压力和体积下囊泡的形态相图.

结论:

  • 丝间相互作用在决定新出现的囊泡形态方面发挥着主导作用.
  • 为人工蜂系统和自适应软机器人提供了定量设计原则.