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Oligosaccharide Assembly01:24

Oligosaccharide Assembly

2.8K
Protein glycosylation starts in the ER lumen and continues in the Golgi apparatus. Glycosyltransferases catalyze the addition of sugar molecules or glycosylation of proteins. Usually, these enzymes add sugars to the hydroxyl groups of selected serine or threonine residues to form O-linked glycans or the amino groups of asparagine residues to form N-linked glycans. Different positions on the same polypeptide chain can contain differently linked glycans.
Multiple sugar molecules that may or may...
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Protein Complex Assembly02:41

Protein Complex Assembly

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Proteins can form homomeric complexes with another unit of the same protein or heteromeric complexes with different types.  Most protein complexes self-assemble spontaneously via ordered pathways, while some proteins need assembly factors that guide their proper assembly. Despite the crowded intracellular environment, proteins usually interact with their correct partners and form functional complexes.
Many viruses self-assemble into a fully functional unit using the infected host cell to...
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Assembly of Cytoskeletal Filaments01:18

Assembly of Cytoskeletal Filaments

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Cytoskeletal filaments are polymeric forms of smaller protein subunits. However, individual cytoskeletal filaments may easily disassemble or associate with other similar filaments to form rigid structures. Microfilaments, made of actin monomers, rely on actin-binding proteins to form bundles and create networks of individual actin filaments. Microtubules rely on microtubule-associated proteins (MAPs) to form sturdy cylindrical structures. However, the proteins involved in forming complex...
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Assembly of Complex Microtubule Structures01:32

Assembly of Complex Microtubule Structures

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Complex microtubule structures are present in resting cells and in dividing cells. In resting cells, they are responsible for maintaining the cellular architecture, tracks for intracellular transport, positioning of organelles, assembly of cilia and flagella. They mediate the bipolar spindle assembly for chromosomal segregation and positioning of the cell division plate in dividing cells. The formation of microtubule complex structures depends on the cell type, cell stage, and cell function.
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Updated: Jun 29, 2025

ECM Protein Nanofibers and Nanostructures Engineered Using Surface-initiated Assembly
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ECM Protein Nanofibers and Nanostructures Engineered Using Surface-initiated Assembly

Published on: April 17, 2014

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メタルアシスト炭水化物組立

Yong Wu1,2, Chun Tang1,2, Jauh Tzuoh Lee3

  • 1Department of Chemistry, The University of Hong Kong, Hong Kong SAR 999077, China.

Journal of the American Chemical Society
|March 29, 2024
PubMed
まとめ
この要約は機械生成です。

研究者は,サイクロフルークトン-6 (CF-6) と金属カチオンを用いた複雑な炭水化物の上部構造を作るための新しい方法を開発しました. 調整可能なナモメカニカル特性を持つ新しい炭水化物ベースの材料の制御された組み立てを可能にします.

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Synthesis of Information-bearing Peptoids and their Sequence-directed Dynamic Covalent Self-assembly
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Synthesis of Information-bearing Peptoids and their Sequence-directed Dynamic Covalent Self-assembly

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Formation of Biomembrane Microarrays with a Squeegee-based Assembly Method
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Formation of Biomembrane Microarrays with a Squeegee-based Assembly Method

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関連する実験動画

Last Updated: Jun 29, 2025

ECM Protein Nanofibers and Nanostructures Engineered Using Surface-initiated Assembly
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ECM Protein Nanofibers and Nanostructures Engineered Using Surface-initiated Assembly

Published on: April 17, 2014

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Synthesis of Information-bearing Peptoids and their Sequence-directed Dynamic Covalent Self-assembly
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Synthesis of Information-bearing Peptoids and their Sequence-directed Dynamic Covalent Self-assembly

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Formation of Biomembrane Microarrays with a Squeegee-based Assembly Method
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Formation of Biomembrane Microarrays with a Squeegee-based Assembly Method

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科学分野:

  • 炭水化物の化学反応
  • 超分子化学
  • 材料科学

背景:

  • 核酸とアミノ酸の配列制御による組成は 革命的な技術です
  • 炭水化物の上部構造は複雑さと柔軟性により ほとんど未調査のままである.

研究 の 目的:

  • サイクロオリゴサッカライドからの階層的な上部構造のボトムアップアセンブリを報告する.
  • 炭水化物の潜在能力を 探求する.

主な方法:

  • 柔軟なサイクロオリゴサカリドであるサイクロフルークトン-6 (CF-6) を利用した.
  • CF-6酸素原子との協調結合を形成するためにアルカリ金属カチオンを使用しています.
  • 拡張フレームワークとその階層的な上部構造の形成を調査した.

主要な成果:

  • 協調結合はCF-6の構造を 硬い構造に閉じ込めました
  • CF-6リガンドは橋渡しされ,多層アセンブリにつながった.
  • 階層的な上部構造を持つ3つの拡張されたフレームワークが形成されました.
  • これらの上部構造は材料のナノメカニカル特性を調節した.

結論:

  • 複雑な炭水化物の上部構造を構築するための新しい方法を示した.
  • 炭水化物の超分子組成の可能性を強調した.
  • 炭水化物ベースの材料科学のさらなる研究を奨励した.