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相关概念视频

G-protein Coupled Receptors01:21

G-protein Coupled Receptors

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G-protein coupled receptors are ligand binding receptors that indirectly affect changes in the cell. The actual receptor is a single polypeptide that transverses the cell membrane seven times creating intracellular and extracellular loops. The extracellular loops create a ligand specific pocket which binds to neurotransmitters or hormones. The intracellular loops holds onto the G-protein.
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Protein and Protein Structure02:15

Protein and Protein Structure

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Proteins are one of the most abundant organic molecules in living systems and have the most diverse range of functions of all macromolecules. Proteins may be structural, regulatory, contractile, or protective. They may serve in transport, storage, or membranes; or they may be toxins or enzymes. Their structures, like their functions, vary greatly. They are all, however, amino acid polymers arranged in a linear sequence.
A protein's shape is critical to its function. For example, an enzyme...
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Structural Protein Function01:56

Structural Protein Function

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Structural proteins are a category of proteins responsible for functions ranging from cell shape and movement to providing support to major structures such as bones, cartilage, hair, and muscles. This group includes proteins such as collagen, actin, myosin, and keratin.
Collagen, the most abundant protein in mammals, is found throughout the body. In connective tissue, such as skin, ligaments, and tendons, it provides tensile strength and elasticity.  In bones and teeth, it mineralizes to...
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G Protein-Coupled Receptors or GPCRs are membrane-bound receptors that transiently associate with heterotrimeric G proteins and induce an appropriate response to sensory stimuli such as light, odors, hormones, cytokines, or neurotransmitters.
GPCRs are also called heptahelical, 7TM, or serpentine receptors, and consist of seven (H1-H7) transmembrane alpha-helices that span the bilayer to form a cylindrical core. The transmembrane helices are connected by three extracellular loops and three...
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质子结合的染色体和蛋白质的结构变化控制了植物染色体激活.

Galaan Merga1, Maximilian Große1, Anastasia Kraskov2

  • 1Humboldt- Universität Zu Berlin, Institut für Biologie, Biophysikalische Chemie, Invalidenstr 42, Berlin D-10115, Germany.

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概括

植物染色体使用质子转移来切换状态,引发结构变化. 这种分子内质子转移对于植物染色体功能和二次结构转换一般来说是必不可少的.

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科学领域:

  • 生物化学 生物化学
  • 分子生物学分子生物学
  • 频谱学是一种光谱学.

背景情况:

  • 植物染色体是控制生理过程的光传感器.
  • 光异构化启动了植物染色体的激活,涉及诸如Meta-Rc.这样的中间状态.
  • 这种Meta-Rc状态对于Pfr形成和植物染色体的舌头结构过渡至关重要.

研究的目的:

  • 研究细菌植物染色体Agp1.1.中的Meta-Rc状态的结构和反应.
  • 阐明质子迁移在植物染色体信号传递中的作用.
  • 确定植物染色体中二级结构转换的机制.

主要方法:

  • 红外 (红外) 差异光谱学.红外 (红外) 差异光谱学.
  • 共振拉曼光谱法. 共振拉曼光谱法.
  • 在不同温度和pH值下研究了Agp1植物染色体.

主要成果:

  • 甲基-Rc的形成涉及染色体化和脱质;衰变涉及反质.
  • 质子迁移触发了舌头的二次结构过渡 (β-sheet/α-helix互转).
  • 在Meta-Rc和Pfr状态中观察到的pH依赖的构造平衡.

结论:

  • 二次结构转换是由染色体连接的质子转移引起的,而不是染色体放松.
  • 内分子质子转移是植物染色体中二级结构转换的先决条件.
  • 这些发现支持了跨不同物种的植物染色体信号传递的一般机制.