Chromophore formation in GFP: Computational modeling of the immature form of wild-type GFP

机译：GFP中的发色团形成：野生型GFP不成熟形式的计算建模

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The main reason green fluorescent protein (GFP) is so useful in molecular imaging is the fact that its chromophore is formed autocatalytically. We have been using molecular mechanics to examine chromophore formation since 1995 that is well before the first crystal structures of GFP were solved. Our calculations have resulted in a number of predictions that have been borne out by subsequent experiments and a number of them that haven't. Recently we have been supplementing these calculations with calculations based on the crystal structures of immature GFP mutants (I.e. the precyclized form). Preliminary results from these calculations have shown that immature GFP does form a tight-turn in the chromophore forming region, and that chromophore cyclization is probably catalyzed in the manner proposed by Getzoff et al (Biochemistry 44: 1960-1970,2005).

机译：绿色荧光蛋白（GFP）在分子成像中是如此有用的主要原因是其发色团是自动催化的。我们一直在使用分子力学来检查自1995年以来的发色团形成，这在解决了GFP的第一晶体结构之前。我们的计算导致了许多预测由随后的实验和其中一些没有。最近，我们已经通过基于未成熟的GFP突变体的晶体结构来补充这些计算（即预定形式）。来自这些计算的初步结果表明，未成熟的GFP确实在发色团形成区域中形成紧匝，并且发色团环化可能以Getzoff等（生物化学44：1960-1970,2005）提出的方式催化。

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《Conference on Genetically Engineered and Optical Probes for Biomedical Applications》|2007年||共7页
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Nathan P. Lemay; Marc Zimmer; SPIE-The International Society for Optical Engineering;
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中图分类光、激光生物医学;
关键词
chromophore; fluorophore; autocatalytic cyclization; green fluorescent protein;

机译：发色团;荧光团;自催化环化;绿色荧光蛋白;

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1. Performance of popular XC-functionals for the description of excitation energies in GFP-like chromophore models [J] . List N.H., Olsen J.M., Rocha-Rinza T., International Journal of Quantum Chemistry . 2012,第3a4期

机译：流行的XC功能在GFP类发色团模型中描述激发能的性能
2. Naphthalene derivatives of a conformationally locked GFP chromophore with large stokes shifts [J] . Baleeva Nadezhda S., Khavroshechkina Anastasia V, Zaitseva Elvira R., Tetrahedron letters: The International Journal for the Rapid Publication of Preliminary Communications in Organic Chemistry . 2019,第34期

机译：具有大型斯托克斯的甲己烷衍生物，具有大型斯托克斯的大型斯托克
3. Conformationally locked GFP chromophore derivatives as potential fluorescent sensors [J] . Baleeva N. S., Yampolsky I. V., Baranov M. S. Russian journal of bioorganic chemistry . 2016,第4期

机译：构象锁定的GFP生色团衍生物作为潜在的荧光传感器
4. Chromophore formation in GFP: Computational modeling of the immature form of wild-type GFP [C] . Nathan P. Lemay, Marc Zimmer Genetically Engineered and Optical Probes for Biomedical Applications IV; Progress in Biomedical Optics and Imaging; vol.8 no.26; Proceedings of SPIE-The International Society for Optical Engineering; vol.6449 . 2007

机译：GFP中的发色团形成：野生型GFP未成熟形式的计算模型
5. Impact of Silver Nanoparticle Transformation on Pseudomonas aeruginosa GFP Biofilm. [D] . Adegboye, Temitope Azeezat. 2016

机译：银纳米粒子转化对铜绿假单胞菌GFP生物膜的影响。
6. Kinetic isotope effect studies on the de novo rate of chromophore formation in fast- and slow-maturing GFP variants [O] . Lauren J. Pouwels, Liping Zhang, Nam H. Chan, -1

机译：动力学同位素效应研究快成熟和慢成熟GFP变体生色团形成的从头速率
7. Supplemental Information 8: Red fluorescence intensity data ofP. tricornutumwild type (wt) and GFP-expressing cell lines (lhcf1-GFP; nr-GFP_3, _4, _5; _6; _9; _10). [O] . -1

机译：补充信息8：红色的红色荧光强度数据。 TricornutumWild类型（WT）和GFP表达细胞系（LHCF1-GFP; NR-GFP_3，_4，_5; _6; _9; _10）。

Chromophore formation in GFP: Computational modeling of the immature form of wild-type GFP

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