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在加密植物体内光谱吸收的变异性 生物蛋白类型.

Kristiaän A Merritt1, Tammi L Richardson1,2

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由于辅助颜料称为 phycobiliproteins,加密植物的颜色变化. 光谱分析显示,在定义的加密植物生物蛋白 (Cr-PBP) 类型中存在显著的变异,这表明了亚型和各种染色体组成.

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吸收性是一种吸收性.吸收 吸收 吸收 吸收染色体的染色体是什么在Cryptomonad中,我们可以使用Crypto.密码植物 (cryptophyte) 是一种生物.这是一种生理性肌肉素.植物性双蛋白蛋白 (phycobiliprotein) 是一种蛋白质.

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科学领域:

  • 生理学生理学是指生理学.
  • 频谱学是一种光谱学.
  • 生物化学 生物化学

背景情况:

  • 密码植物表现出多样化的色彩,主要是由于 phycobiliprotein 配件颜料.
  • 九种加密植物生物蛋白 (Cr-PBP) 类型由它们的最大吸收波长来定义.
  • 关于Cr-PBP类型中光谱吸收变量的信息有限.

研究的目的:

  • 在加密植物物种中研究Cr-PBPs的光谱吸收变异性.
  • 描述吸收最大值,二次峰值和FWHM的变化.
  • 为Cr-PBP类型提出精细的分类标准.

主要方法:

  • 从75种加密植物菌株 (55种) 提取Cr-PBPs.
  • 在全光谱辐射下对提取的Cr-PBPs进行光谱分析.
  • 测量初级和二级峰值吸收波长和FWHM.

主要成果:

  • 在Cr-PBP类型中观察到大量的光谱形状差异.
  • Cr-Phycoerythrin (Cr-PE) 545显示出很高的变异性,可能表明2-3个亚型.
  • Cr-PE 566的光谱显示出最小的差异 (±1 nm).

结论:

  • Cr-PBP类型分类可能需要的不仅仅是最大吸收波长.
  • 光谱变化表明Cr-PBP类型中的染色体组成不同.
  • 一些加密植物物种可能含有多个Cr-PBP.