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相关概念视频

Repressible Operon: trp Operon01:21

Repressible Operon: trp Operon

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The trp operon in Escherichia coli exemplifies a repressible operon. It regulates the synthesis of tryptophan through repressor-mediated transcriptional control and attenuation. This dual regulatory mechanism ensures tryptophan biosynthesis occurs only when needed, conserving cellular resources.Structure of the trp OperonThe trp operon consists of five structural genes (trpE, trpD, trpC, trpB, and trpA) that encode enzymes for tryptophan biosynthesis. These genes are transcribed as a single...
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Types of RNA01:23

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Overview
Three main types of RNA are involved in protein synthesis: messenger RNA (mRNA), transfer RNA (tRNA), and ribosomal RNA (rRNA). These RNAs perform diverse functions and can be broadly classified as protein-coding or non-coding RNA. Non-coding RNAs play important roles in the regulation of gene expression in response to developmental and environmental changes. Non-coding RNAs in prokaryotes can be manipulated to develop more effective antibacterial drugs for human or animal use.
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Transcription Attenuation in Prokaryotes02:42

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Transcriptional attenuation occurs when RNA transcription is prematurely terminated due to the formation of a terminator mRNA hairpin structure.  Bacteria use these hairpins to regulate the transcription process and control the synthesis of several amino acids including histidine, lysine, threonine, and phenylalanine. Transcription attenuation takes place in the non-coding regions of mRNA.
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Translational Regulation01:29

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Translational regulation in prokaryotes ensures efficient protein synthesis by controlling ribosome access to mRNA. This regulation is mediated by secondary RNA structures, including translational riboswitches, RNA thermometers, and small RNAs (sRNAs), which respond to intracellular and environmental signals to modulate gene expression.Translational RiboswitchesRiboswitches in the leader region of mRNAs can regulate translation by altering the accessibility of the Shine-Dalgarno (SD) sequence,...
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Stringent Response in E. coli01:23

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Bacterial growth is closely tied to nutrient availability, with cells proliferating exponentially under favorable conditions and entering a stationary phase when resources become scarce. This transition is mediated by a regulatory mechanism known as the stringent response, which allows bacteria to adapt to nutrient deprivation by modulating gene expression and metabolic activity.During nutrient scarcity, intracellular amino acid levels decline. It results in the accumulation of uncharged tRNAs...
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Riboswitches01:56

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Riboswitches are non-coding mRNA domains that regulate the transcription and translation of downstream genes without the help of proteins. Riboswitches bind directly to a metabolite and can form unique stem-loop or hairpin structures in response to the amount of the metabolite present. They have two distinct regions – a metabolite-binding aptamer and an expression platform.
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基于RNA结合衰减蛋白的可编程托响应生物传感器,用于菌株优化.

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  • 1Key Laboratory of Carbohydrate Chemistry and Biotechnology, Ministry of Education, Jiangnan University, Wuxi 214122, China.

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概括

研究人员使用TRAP系统在大肠杆菌中开发了新型的托生物传感器,改善了动态范围和响应值,以增强菌株工程和代谢网络调节.

关键词:
埃舍里希亚大肠杆菌 (Escherichia coli) 是一个大肠杆菌.这就是TRAP TRAP.生物传感器生物传感器高通量选的高通量选分子动力学模拟,分子动力学模拟托芬三聚氨酸是什么

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科学领域:

  • 微生物学 微生物学
  • 合成生物学 合成生物学
  • 生物技术是生物技术.

背景情况:

  • 生物传感器对于高通量菌株选和代谢网络调节至关重要.
  • 目前的托芬传感器在动态范围和响应值方面存在局限性.

研究的目的:

  • 使用TRAP系统在大肠杆菌中开发出新型的托敏感生物传感器.
  • 设计和优化这些生物传感器以提高性能.
  • 利用生物传感器选酶变体并研究代谢途径.

主要方法:

  • 在大肠杆菌中设计的以酸激活的RNA结合衰减蛋白 (TRAP) 为基础的生物传感器.
  • 微调的TRAP表达和优化的TRAP-领袖序列交互.
  • 在托生物合成途径中选了TRAP变异和有益酶变异.
  • 采用分子动力学模拟来研究酶催化机制.

主要成果:

  • 开发了两种具有独特动态范围 (高达22.1倍) 的新型托生物传感器.
  • 达到的响应值低至0-2.2g/L.
  • 在托生物合成中成功选了限制速率酶的有益变体.
  • 通过分子动力学模拟,提供了对酶催化机制的见解.

结论:

  • 开发的基于TRAP的生物传感器提供了改进的工具,用于设计高托产生的菌株.
  • 这项研究提出了设计强大而敏感的生物传感器的新策略.
  • 这些发现有助于代谢工程和合成生物学的进步.