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相关概念视频

Catalytically Perfect Enzymes01:07

Catalytically Perfect Enzymes

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The theory of catalytically perfect enzymes was first proposed by W.J. Albery and J. R. Knowles in 1976. These enzymes catalyze biochemical reactions at high-speed. Their catalytic efficiency values range from 108-109 M-1s-1. These enzymes are also called 'diffusion-controlled' as the only rate-limiting step in the catalysis is that of the substrate diffusion into the active site. Examples include triose phosphate isomerase, fumarase, and superoxide dismutase.
 
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Introduction to Mechanisms of Enzyme Catalysis01:13

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For many years, scientists thought that enzyme-substrate binding took place in a simple "lock-and-key" fashion. This model stated that the enzyme and substrate fit together perfectly in one instantaneous step. However, current research supports a more refined view scientists call induced fit. The induced-fit model expands upon the lock-and-key model by describing a more dynamic interaction between enzyme and substrate. As the enzyme and substrate come together, their interaction causes...
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Enzymes02:34

Enzymes

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Inside living organisms, enzymes act as catalysts for many biochemical reactions involved in cellular metabolism. The role of enzymes is to reduce the activation energies of biochemical reactions by forming complexes with its substrates. The lowering of activation energies favor an increase in the rates of biochemical reactions.
Enzyme deficiencies can often translate into life-threatening diseases. For example, a genetic abnormality resulting in the deficiency of the enzyme G6PD...
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Turnover Number and Catalytic Efficiency01:19

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The turnover number of an enzyme is the maximum number of substrate molecules it can transform per unit time. Turnover numbers for most enzymes range from 1 to 1000 molecules per second. Catalase has the known highest turnover number, capable of converting up to 2.8×106 molecules of hydrogen peroxide into water and oxygen per second. Lysozyme has the lowest known turnover number of half a molecule per second.
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Introduction to Enzymes01:22

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The use of enzymes by humans dates to 7000 BCE. Humans first used enzymes to ferment sugars and produce alcohol without knowing that this was an enzyme-catalyzed reaction. Wilhelm Kuhne coined the term 'enzyme' in 1877 from the Greek words ‘en’ meaning ‘in’ or ‘within’ and ‘zyme’ meaning ‘yeast.’
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Ribozymes02:47

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The term ribozyme is used for RNA that can act as an enzyme. Ribozymes are mainly found in selected viruses, bacteria, plant organelles, and lower eukaryotes. Ribozymes were first discovered in 1982 when Tom Cech’s laboratory observed Group I introns acting as enzymes. This was shortly followed by the discovery of another ribozyme, Ribonulcease P, by Sid Altman’s laboratory. Both Cech and Altman received the Nobel Prize in chemistry in 1989 for their work on ribozymes.
Ribozymes can...
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DNA催化:设计,功能和优化

Rebecca L Stratton1, Bishal Pokhrel1, Bryce Smith1

  • 1Department of Chemistry and Biochemistry, Kent State University, Kent, OH 44242, USA.

Molecules (Basel, Switzerland)
|November 9, 2024
PubMed
概括
此摘要是机器生成的。

DNA催化剂或DNA酶提供可调和特定的催化功能. 本综述涵盖了传统的DNA酶和新型DNA酶混合体,强调了它们的性能和针对先进应用的优化.

关键词:
在DNA催化过程中,这是一种DNA-纳米粒子混合体.这就是DNAzyme DNA酶.设计 设计 设计 设计功能 功能 功能 功能 功能优化的优化优化优化.

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科学领域:

  • 生物化学 生物化学
  • 催化剂是一种催化剂.
  • 分子生物学分子生物学

背景情况:

  • 催化DNA (DNA酶) 越来越多地因其效率,特异性和可调性而得到认可.
  • DNA的结构复杂性使得它能够在基因存储之外发挥多种功能,包括催化.
  • 光谱学的进步有助于理解DNA催化剂机制.

研究的目的:

  • 审查传统DNAzymes的性能和优化策略.
  • 分析DNAzyme混合催化剂的独特特性和潜力.
  • 提供对DNA催化最新发展的深入概述.

主要方法:

  • 关于DNAzymes和DNAzyme杂交物的最近研究的文献综述.
  • 分析光谱技术以获得机械洞察力.
  • 对催化剂性能和优化信息的综合.

主要成果:

  • DNA酶表现出广泛的催化活动,包括电催化和酶选择性.
  • DNA酶杂交物呈现出新且有前途的催化特性.
  • 理性结构优化可以提高DNA催化剂的性能.

结论:

  • 催化DNA代表了开发高效和特定催化剂的强大平台.
  • 对DNA酶杂交物的进一步研究将解锁新的催化应用.
  • 了解DNA催化剂机制是未来优化和设计的关键.