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相关概念视频

Protein Transport to the Inner Chloroplast Membrane01:18

Protein Transport to the Inner Chloroplast Membrane

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Proteins targeted to the inner chloroplast membrane, or plastid proteins, are transported by two general pathways: the stop-transfer and the re-insertion or post-import pathways. Most plastid proteins carry N-terminal transit sequences and internal import sequences targeting it to the specific chloroplast subcompartment. Proteins targeted by the stop-transfer pathway have internal hydrophobic sequences that inhibit their translocation into the stroma. As a result, these precursors are arrested...
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Protein Transport into the Inner Mitochondrial Membrane01:34

Protein Transport into the Inner Mitochondrial Membrane

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Nuclear encoded mitochondrial precursors are imported to the inner membrane in a multistep process involving two separate translocons, TIM22 and TIM23. TIM23 is a cation-selective pore that remains closed by the N terminal segment of the protein. Negative charges on the TIM23 act as a receptor for the incoming precursor, pulling the positively charged matrix-targeting sequence for peptide insertion and translocation.
Transport of mitochondrial precursors across the TIM23 channel is driven by...
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Insertion of Single-pass Transmembrane Proteins in the RER01:26

Insertion of Single-pass Transmembrane Proteins in the RER

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Integral membrane proteins are proteins adhered to the lipid bilayer of a cell organelle or membrane. They can be of two types: transmembrane integral proteins that span the lipid bilayer and monotopic proteins that are attached to either side of the membrane but do not pass through it.
Integral transmembrane proteins possess transmembrane and extra membrane domains. The transmembrane domains are primarily made of 20-25 hydrophobic amino acids arranged in a helical secondary confirmation. These...
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Translocation of Proteins into the Mitochondria01:19

Translocation of Proteins into the Mitochondria

8.8K
Mitochondrial precursors are translocated to the internal subcompartments via independent mechanisms involving distinct protein machineries called translocases.
Sorting of outer membrane proteins:
Mitochondrial outer membrane proteins are of two types: the transmembrane, beta-barrel porins, and the membrane-anchored, alpha-helical proteins. Beta-barrel porin precursors are translocated by the TOM complex and inserted into the outer mitochondrial membrane by the SAM complex. In contrast,...
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Insertion of Multi-pass Transmembrane Proteins in the RER01:29

Insertion of Multi-pass Transmembrane Proteins in the RER

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The rough ER membrane synthesizes, assembles, and embeds transmembrane proteins in diverse topologies. These proteins function as transporters or channels and can remain in the ER membrane or are sent to the Golgi complex, lysosome, and cell membrane.
The multipass transmembrane proteins are the type IV integral membrane proteins with multiple topogenic sequences determining their spatial arrangement in the ER membrane. Nearly all multipass proteins lack a cleavable signal sequence and use...
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Protein Transport to the Thylakoids01:22

Protein Transport to the Thylakoids

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Thylakoids are membrane-bound sac-like structures within the chloroplast that serve as sites for photosynthesis. Thylakoid lumen contains many electron transport proteins and is enclosed by a thylakoid membrane rich in the light-harvesting complex. Proteins targeted to the thylakoids are transported as precursors and are sorted by the general TOC/TIC import pathway. Once the precursor reaches the stroma, stromal processing peptidases remove their transit signal and expose thylakoid signal...
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相关实验视频

Updated: May 3, 2026

Imaging Integrin Tension and Cellular Force at Submicron Resolution with an Integrative Tension Sensor
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Imaging Integrin Tension and Cellular Force at Submicron Resolution with an Integrative Tension Sensor

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在1D TiS2 ((en) 链中插入.

Tianyang Li1, Yi-Hsin Liu, Basant Chitara

  • 1Department of Chemistry and Biochemistry, The Ohio State University , Columbus, Ohio 43210, United States.

Journal of the American Chemical Society
|February 14, 2014
PubMed
概括
此摘要是机器生成的。

在1D范德瓦尔斯固体TiS2中实现了可逆间隔. 这一过程通过注入电子显著降低了电阻,并提供了调整材料性能的新方法.

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A TIRF Microscopy Technique for Real-time, Simultaneous Imaging of the TCR and its Associated Signaling Proteins
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Single-Molecule Imaging of Lateral Mobility and Ion Channel Activity in Lipid Bilayers using Total Internal Reflection Fluorescence TIRF Microscopy
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相关实验视频

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Imaging Integrin Tension and Cellular Force at Submicron Resolution with an Integrative Tension Sensor
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A TIRF Microscopy Technique for Real-time, Simultaneous Imaging of the TCR and its Associated Signaling Proteins
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Single-Molecule Imaging of Lateral Mobility and Ion Channel Activity in Lipid Bilayers using Total Internal Reflection Fluorescence TIRF Microscopy
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科学领域:

  • 材料科学 材料科学 材料科学
  • 固态化学 固态化学
  • 凝聚物质物理学 凝聚物质物理学

背景情况:

  • 金属的插入到二维分层材料中产生了独特的电子,磁性和相关性质.
  • 在低维 (1D,2D) 材料中探索间隙对于发现新功能至关重要.

研究的目的:

  • 为了研究中介在1D范德瓦尔斯固体TiS2 (乙二胺) 中的可行性和影响.
  • 探索通过可逆间隔调整来调整减小尺寸材料的物理性质的潜力.

主要方法:

  • 有机/无机混合物1D范德瓦尔斯固体TiS2的合成.
  • 实验证明可逆 (Li) 插入到TiS2 ((乙二胺) 格子中的可逆 (Li) 插入.
  • 测量电阻变化在Li间隔时发生的变化.

主要成果:

  • 在TiS2中证明了成功的可逆间隔.
  • 间隙导致Ti(4+) 减少为Ti(3+) 并将电子注入网格.
  • 在间歇后观察到电阻的显著,数量级的下降.

结论:

  • 可逆的Li间隙在1D范德瓦尔斯固体中是可以实现的,如TiS2 ((乙二胺)).
  • 这个过程提供了一个可行的途径来调节电子属性,特别是电阻.
  • 这些发现为新兴的缩小尺寸材料的性能调整开辟了道路.