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相关概念视频

Master Transcription Regulators02:23

Master Transcription Regulators

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Master transcription regulators are regulatory proteins that are predominantly responsible for regulating the expression of multiple genes. Often these genes work in concert to drive a  complex process. Activation of a master transcription regulator can lead to a cascade of transcriptional activation necessary for that outcome. These regulators can directly bind to the regulatory sequences of the various genes involved, or they can indirectly regulate transcription by binding to regulatory...
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Prokaryotic Transcriptional Activators and Repressors01:58

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The organization of prokaryotic genes in their genome is notably different from that of eukaryotes. Prokaryotic genes are organized, such that the genes for proteins involved in the same biochemical process or function are located together in groups. This group of genes, along with their regulatory elements, are collectively known as an operon. The functional genes in an operon are transcribed together to give a single strand of mRNA known as polycistronic mRNA.
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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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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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A Hydroponic Co-cultivation System for Simultaneous and Systematic Analysis of Plant/Microbe Molecular Interactions and Signaling
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对比转录学揭示了一个高度多态的Xanthomonas HrpG病毒性 regulon.

Thomas Quiroz Monnens1, Brice Roux1, Sébastien Cunnac2

  • 1LIPME, INRAE/CNRS UMR 0441/2594, Université de Toulouse, Université Paul Sabatier Toulouse 3, UMR, Castanet-Tolosan, 31320, France.

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在Xanthomonas作物中,HrpG调节了细菌的毒性. 这项研究揭示了跨菌株的多种HrpG规律,显示了超出III型分泌系统的毒性和适应的各种策略.

关键词:
克桑托蒙纳斯 (Xanthomonas) 是一种这就是HrpG.监管多样性的规则转录基因组序列的测序第三种类型的分泌系统.

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科学领域:

  • 微生物学 微生物学
  • 植物病理学 植物病理学
  • 细菌遗传学 细菌遗传学

背景情况:

  • 克桑托莫纳斯细菌会导致重要的作物疾病.
  • 病毒性取决于由III型分泌系统 (T3SS) 提供的III型因子 (T3Es).
  • HrpG是T3SS的主调节器,但其更广泛的调节是研究不足的.

研究的目的:

  • 在多种不同的Xanthomonas物种中研究HrpG regulon.
  • 了解HrpG在T3SS监管之外的作用.

主要方法:

  • 17个Xanthomonas菌株的转录基因组测序.
  • 活性HrpG形式 (HrpG*) 的构成表达,以诱导调节.

主要成果:

  • 在Xanthomonas物种之间和物种内部观察到HrpG* regulons的显著多样性.
  • 核心HrpG* regulon包括T3SS基因,HrpX,T3Es XopR和XopL,一个MFS传送器,以及PhoC.
  • 通过HrpG*对化学反应和碳水化合物/蛋白酶基因的可变调节.

结论:

  • 依赖HrpG的毒性采用各种各样的,特定于菌株的策略.
  • HrpG 调节了超越 T3Es 和 T3SS 的毒性和适应途径.