色氨酸拉链:稳定的单体β-发夹结构
Tryptophan zippers: stable, monomeric beta -hairpins.
作者信息
Cochran A G, Skelton N J, Starovasnik M A
机构信息
Department of Protein Engineering, Genentech, Inc., 1 DNA Way, South San Francisco, CA 94080, USA.
出版信息
Proc Natl Acad Sci U S A. 2001 May 8;98(10):5578-83. doi: 10.1073/pnas.091100898. Epub 2001 May 1.
Abstract
A structural motif, the tryptophan zipper (trpzip), greatly stabilizes the beta-hairpin conformation in short peptides. Peptides (12 or 16 aa in length) with four different turn sequences are monomeric and fold cooperatively in water, as has been observed previously for some hairpin peptides. However, the folding free energies of the trpzips exceed substantially those of all previously reported beta-hairpins and even those of some larger designed proteins. NMR structures of three of the trpzip peptides reveal exceptionally well-defined beta-hairpin conformations stabilized by cross-strand pairs of indole rings. The trpzips are the smallest peptides to adopt an unique tertiary fold without requiring metal binding, unusual amino acids, or disulfide crosslinks.
摘要
一种结构基序——色氨酸拉链(trpzip),能极大地稳定短肽中的β-发夹构象。与之前观察到的一些发夹肽一样,含有四种不同转角序列的肽(长度为12或16个氨基酸)呈单体形式且在水中协同折叠。然而,色氨酸拉链的折叠自由能大大超过了之前报道的所有β-发夹,甚至超过了一些更大的设计蛋白质。三种色氨酸拉链肽的核磁共振结构显示,由吲哚环的跨链对稳定的β-发夹构象异常明确。色氨酸拉链是最小的能采用独特三级折叠的肽,无需金属结合、特殊氨基酸或二硫键交联。
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A Designed beta-Hairpin Containing a Natural Hydrophobic Cluster This research was supported by the National Science Foundation (CHE-9820952). J.F.E. was supported by a fellowship from the Ministerio de Educacion y Cultura (Spain) and the Fulbright Commission. The mass spectrometer was purchased in part with a National Science Foundation grant (CHE-9520868), and the NMR spectrometers were purchased in part with a National Institute Of Health grant (1 S10 RR04981). The CD spectrometer and analytical ultracentrifuge are part of the UW Biophysics Instrumentation Facility (NSF BIR-9512577).
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