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関連する概念動画

What is an Electrochemical Gradient?01:26

What is an Electrochemical Gradient?

118.7K
Adenosine triphosphate, or ATP, is considered the primary energy source in cells. However, energy can also be stored in the electrochemical gradient of an ion across the plasma membrane, which is determined by two factors: its chemical and electrical gradients.
The chemical gradient relies on differences in the abundance of a substance on the outside versus the inside of a cell and flows from areas of high to low ion concentration. In contrast, the electrical gradient revolves around an...
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Secondary Active Transport01:55

Secondary Active Transport

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One example of how cells use the energy contained in electrochemical gradients is demonstrated by glucose transport into cells. The ion vital to this process is sodium (Na+), which is typically present in higher concentrations extracellularly than in the cytosol. Such a concentration difference is due, in part, to the action of an enzyme “pump” embedded in the cellular membrane that actively expels Na+ from a cell. Importantly, as this pump contributes to the high concentration of...
123.0K
Voltaic/Galvanic Cells02:47

Voltaic/Galvanic Cells

45.6K
Spontaneous Chemical Reactions
Spontaneous redox reactions occur abundantly in nature. The chemical reaction occurring in a disposable AA battery powering our remote controls is one such example of a spontaneous redox reaction. Another example is the immersion of coiled copper wire into an aqueous silver nitrate solution. The reaction shows a gradual, visually impressive color change from colorless to bright blue and the formation of a grey precipitate on the copper wire. In this experiment,...
45.6K
Transcellular Transport of Solutes01:23

Transcellular Transport of Solutes

4.0K
Transcellular transport of solutes is the movement of substances like monosaccharides and amino acids through polarized cells. This transport mechanism is primarily seen in epithelial and endothelial cells aided by membrane transport proteins such as channels and transporters. The tight junctions between these cells confine the membrane proteins to the two sides of the cell. The epithelial cells have distinct apical and basolateral domains. In contrast, the endothelial cells show the luminal...
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Chemotaxis and Direction of Cell Migration01:21

Chemotaxis and Direction of Cell Migration

5.0K
Cells can detect chemical cues in their environment and reorganize the cytoskeleton to migrate toward them or away from them. This directional migration, called chemotaxis, is essential during embryogenesis and development, immune response, tissue repair and regeneration, and reproduction. These chemical cues can either attract or repel the cell's movement. For example, axon development is determined by a combination of chemoattractants and chemorepellents that direct the growing axon...
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Electrochemical Gradient and Channel Proteins: An Overview01:21

Electrochemical Gradient and Channel Proteins: An Overview

4.9K
An electrochemical gradient is a fundamental concept in biology and chemistry. It regulates the movement of ions across cell membranes. This movement is influenced by two factors:
The electrical gradient: The electrical gradient across cell membranes refers to the difference in electric charge between the inside and outside of a cell.  This difference drives the movement of ions towards or away from the cells. For instance, if the inside of the cell is more negatively charged relative to...
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関連する実験動画

Updated: May 6, 2026

A Gradient-generating Microfluidic Device for Cell Biology
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A Gradient-generating Microfluidic Device for Cell Biology

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アフィニティ・グラディエントは,銅を細胞の宛先へと駆り立てます.

Lucia Banci1, Ivano Bertini, Simone Ciofi-Baffoni

  • 1Magnetic Resonance Center CERM and Department of Chemistry, University of Florence, Via Luigi Sacconi 6, 50019, Sesto Fiorentino, Florence, Italy.

Nature
|May 14, 2010
PubMed
まとめ

細胞の銅の分布は,タンパク質の結合親和によって支配される. この研究は,銅の結合親和性を定量化し,親和度差を利用して,銅が細胞経路に沿ってどのように移動するかを明らかにしました.

科学分野:

  • バイオケミストリー バイオケミストリー
  • 細胞生物学 細胞生物学
  • トレースエレメントの代謝

背景:

  • 銅は必須だが有毒である;細胞は細胞内自由銅を厳格に規制する.
  • セルラー銅密輸システムは,毒性を防止しながら栄養素供給を確保します.
  • タンパク質の銅結合親和性に関する以前のデータは矛盾し,比較不可能でした.

研究 の 目的:

  • 主要な細胞内銅タンパク質に対する明らかなCu (I) 結合親和性を決定する.
  • タンパク質パートナー間の銅の転送を促す要因を合理化する.
  • セルラー銅の分布のための熱力学的基礎を提供するために.

主な方法:

  • 統一された電気スプレーイオン化質量スペクトロメトリ (ESI-MS) ベースの戦略が採用されました.
  • 測定は細胞のリドックス環境で行われました.
  • 銅のタンパク質の代表的なセットに対して,明らかにCu (I) 結合の親和性が決定された.

主要な成果:

  • 銅は,銅結合親和度の上昇のグラデーションを利用して,タンパク質の部位間で移動する.
  • 高親和性銅結合タンパク質には,メタロチオニンとCu,Zn-SOD1.1が含まれています.

さらに関連する動画

Creating Adhesive and Soluble Gradients for Imaging Cell Migration with Fluorescence Microscopy
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Creating Adhesive and Soluble Gradients for Imaging Cell Migration with Fluorescence Microscopy

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Polydimethylsiloxane-polycarbonate Microfluidic Devices for Cell Migration Studies Under Perpendicular Chemical and Oxygen Gradients
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Polydimethylsiloxane-polycarbonate Microfluidic Devices for Cell Migration Studies Under Perpendicular Chemical and Oxygen Gradients

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関連する実験動画

Last Updated: May 6, 2026

A Gradient-generating Microfluidic Device for Cell Biology
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Creating Adhesive and Soluble Gradients for Imaging Cell Migration with Fluorescence Microscopy
13:10

Creating Adhesive and Soluble Gradients for Imaging Cell Migration with Fluorescence Microscopy

Published on: April 4, 2013

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Polydimethylsiloxane-polycarbonate Microfluidic Devices for Cell Migration Studies Under Perpendicular Chemical and Oxygen Gradients
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Polydimethylsiloxane-polycarbonate Microfluidic Devices for Cell Migration Studies Under Perpendicular Chemical and Oxygen Gradients

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  • 熱力学データは,細胞の銅分布における運動過程を説明する.
  • 結論:

    • 細胞の銅の分布は,タンパク質とタンパク質の相互作用と特定の認識のネットワークに依存しています.
    • 銅結合親近性のグラデーションは,細胞経路に沿って銅の動きを決定する.
    • この研究は,銅のホメオスタシスを理解するための重要な熱力学データを提供しています.