Jove
Visualize
お問い合わせ
JoVE
x logofacebook logolinkedin logoyoutube logo
JoVEについて
概要リーダーシップブログJoVEヘルプセンター
著者向け
出版プロセス編集委員会範囲と方針査読よくある質問投稿
図書館員向け
推薦の声購読アクセスリソース図書館諮問委員会よくある質問
研究
JoVE JournalMethods CollectionsJoVE Encyclopedia of Experimentsアーカイブ
教育
JoVE CoreJoVE BusinessJoVE Science EducationJoVE Lab Manual教員リソースセンター教員サイト
利用規約
プライバシーポリシー
ポリシー

関連する概念動画

Protein Folding01:22

Protein Folding

Overview
Protein Folding01:25

Protein Folding

Proteins are chains of amino acids linked together by peptide bonds. Upon synthesis, a protein folds into a three-dimensional conformation, critical to its biological function. Interactions between its constituent amino acids guide protein folding, and hence the protein structure is primarily dependent on its amino acid sequence.
Protein Structure Is Critical to Its Biological Function
Proteins perform a wide range of biological functions such as catalyzing chemical reactions, providing...
Protein Folding01:22

Protein Folding

Overview
Molecular Chaperones and Protein Folding03:00

Molecular Chaperones and Protein Folding

The native conformation of a protein is formed by interactions between the side chains of its constituent amino acids. When the amino acids cannot form these interactions, the protein cannot fold by itself and needs chaperones. Notably, chaperones do not relay any additional information required for the folding of polypeptides; the native conformation of a protein is determined solely by its amino acid sequence. Chaperones catalyze protein folding without being a part of the folded protein.
The...
Molecular Chaperones and Protein Folding03:00

Molecular Chaperones and Protein Folding

The native conformation of a protein is formed by interactions between the side chains of its constituent amino acids. When the amino acids cannot form these interactions, the protein cannot fold by itself and needs chaperones. Notably, chaperones do not relay any additional information required for the folding of polypeptides; the native conformation of a protein is determined solely by its amino acid sequence. Chaperones catalyze protein folding without being a part of the folded protein.
The...
Amyloid Fibrils03:03

Amyloid Fibrils

Amyloid fibrils are aggregates of misfolded proteins.  Under most circumstances, misfolded proteins are either refolded by chaperone proteins or degraded by the proteasome. However, in the case of a mutation or a disease, these proteins can accumulate to form large clusters and often further assemble to form elongated fibers, called fibrils. 
Amyloid deposits were observed as early as 1639 in the liver and the spleen.   In 1854, Rudolph Virchow performed iodine staining, normally used to...

こちらも読む

関連記事

共著者、ジャーナル、引用グラフによってこの研究に関連する記事。

並び替え
Same author

Nonequilibrium Theory for Molecular Machine Design.

ArXiv·2026
Same author

Seeking Biology's Physics Stories: Simplify, Simplify.

Annual review of biophysics·2026
Same author

A principled basis for nonequilibrium network flows.

Nature communications·2026
Same author

Fluctuation-Response Design Rules for Nonequilibrium Flows.

ArXiv·2026
Same author

"Excluded phenotypes" restrict genetic paths toward adaptation in declining populations.

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

Modeling Protein-Protein and Protein-Ligand Interactions by the ClusPro Team in CASP16.

Proteins·2025

関連する実験動画

Updated: May 16, 2026

Interview: Protein Folding and Studies of Neurodegenerative Diseases
19:50

Interview: Protein Folding and Studies of Neurodegenerative Diseases

Published on: July 16, 2008

タンパク質の折り畳み問題は,50年後のこと.

Ken A Dill1, Justin L MacCallum

  • 1Laufer Center for Physical and Quantitative Biology, Stony Brook University, Stony Brook, NY 11794-5252, USA. dill@laufercenter.org

Science (New York, N.Y.)
|November 28, 2012
PubMed
まとめ

半世紀前の課題であるタンパク質の折り畳みを理解することは,著しく進歩しました. 現在,コンピュータ・シミュレーションとデータベースは,タンパク質の構造を予測し,その急速な折り畳みメカニズムを理解するのに役立ちます.

科学分野:

  • バイオフィジックス 生物物理学
  • コンピュータ生物学 コンピュータ生物学
  • 構造生物学 構造生物学とは

背景:

  • タンパク質の折りたたみ問題は,約50年前に始まり,アミノ酸配列がタンパク質の構造,折りたたみ速度,構造予測をどのように決定するかに対処しています.
  • それは,物理化学と分子生物学における基本的な問いを網羅しています.

研究 の 目的:

  • タンパク質の折り畳み問題の3つの核心問題に対処する上で達成された進展をレビューする.
  • タンパク質構造の決定の物理的原理と計算的アプローチの理解における進歩を強調する.

主な方法:

  • 科学文献とコンピューティングシミュレーションデータのレビュー.
  • タンパク質データバンク (PDB) のタンパク質構造データ分析.

主要な成果:

  • 詳細なモデルを用いたコンピュータ・シミュレーションにより,小さなタンパク質の折り畳みを予測することが成功しました.
  • 熱運動によりタンパク質は急速に折り畳み,安定した原生構造へと駆り立てられ,フンネル状のエネルギー景観によって視覚化されます.
  • 構造予測の精度は劇的に改善されており,その多くは広範な構造データの利用可能性によるものです.

結論:

さらに関連する動画

Microfluidic Mixers for Studying Protein Folding
12:42

Microfluidic Mixers for Studying Protein Folding

Published on: April 10, 2012

Analysis of Protein Folding, Transport, and Degradation in Living Cells by Radioactive Pulse Chase
08:59

Analysis of Protein Folding, Transport, and Degradation in Living Cells by Radioactive Pulse Chase

Published on: February 12, 2019

関連する実験動画

Last Updated: May 16, 2026

Interview: Protein Folding and Studies of Neurodegenerative Diseases
19:50

Interview: Protein Folding and Studies of Neurodegenerative Diseases

Published on: July 16, 2008

Microfluidic Mixers for Studying Protein Folding
12:42

Microfluidic Mixers for Studying Protein Folding

Published on: April 10, 2012

Analysis of Protein Folding, Transport, and Degradation in Living Cells by Radioactive Pulse Chase
08:59

Analysis of Protein Folding, Transport, and Degradation in Living Cells by Radioactive Pulse Chase

Published on: February 12, 2019

  • 過去半世紀,タンパク質の折り畳み問題を解決するうえで大きな進展がみられた.
  • この分野は,物理学,化学,生物学を統合した"タンパク質物理科学"へと進化しました.
  • 継続的な研究は,タンパク質の構造を理解し,操作する上でさらなる飛躍を約束します.