NMR法研究天花粉蛋白TDK肽片段的溶液构象

用ＨＮＭＲ法测定ＴＤＫ肽在Ｈ２Ｏ（ＨＯＤＫ）,５０％六氟丙醇（ＦＰＤＫ）和２ｍｏｌ／ＬＧｕ．ＨＣｌ（ＧＵＤＫ）溶液构象。在ＨＯＤＫ和ＦＰＤＫ中,ＴＤＫ肽的两段序列Ａｓｐ０－Ｉｌｅ４,Ｓｅｒ９－Ｉｌｉ１７分别具有较稳定的α－螺旋含量;而ＧＵＤＫ的ＳＡＬＳ序列仍能检测到有序残存结构。并假设ＳＡＬＳ序列是肽链形成二级结构的原始核心。     

NMR法研究天花粉蛋白T14肽片段的溶液构象

本文报道用１ＨＮＭＲ法测定Ｔ１４肽在ＤＭＳＯ（ＭＳ１４）,Ｈ２Ｏ（ＨＯ１４）,５０％甲醇（ＭＥ１４）和５０％六氟异丙醇（ＦＰ１４）中的溶液构象。通过ＮＯＥ效应,偶合常数,Ｈ／Ｄ交换速率表征和定位二级结构和疏水域,计算两面角φ和螺旋形成几率。结果表明序列Ｓｅｒ９～Ｔｌｅ１７在ＨＯ１４中较为有序,存在强流水作用。推测是类似螺旋样的亚稳结构;而在ＤＭＳＯ中序列ＳＡＬＳＫＱ存在形成α－螺旋结构的可能性,且六氟异丙醇（ＨＦＰ）促进α－螺旋的稳定性,并综合分析Ｈ２Ｏ,ＤＭＳＯ,ＭｅＯＨ和ＨＦＰ４种溶剂对Ｔ１４肽二级结构形成的作用。     

天花粉蛋白T18肽片段的溶液构象及T14、TDK和T18肽构象比较

用１ＨＮＭＲ法测定Ｔ１８肽在ＤＭＳＯ（ＭＳ１８）和５０％六氟异丙醇（ＦＰ１８）中的溶液构象．ＭＳ１８含有Ｉｌｅ３～Ｇｌｎ７和Ａｌａ１２～Ｇｌｎ１６两段β－折叠链;而ＦＰ１８则转变为α－螺旋结构。综合分析Ｔ１４,Ｔ１８和ＴＤＫ三个模型肽的结构性质和稳定性,比较肽链序列和溶剂作用,提出肽链局部优势结构的概念,并据此讨论天花粉蛋白小结构域折叠起始过程．     

天花粉蛋白T18肽片段的溶液构象及T14,TDK和T18肽…

用＾１Ｈ ＮＭＲ法测定Ｔ１８肽在ＤＭＳＯ（ＭＳ１８）和５０％六氟异丙醇（ＦＰ１８）中的溶液构象。ＭＳ１８含有Ｉｌｅ３￣Ｇｌｕ７和Ａｌａ１２￣Ｇｌｎ１６两段β－折叠链;而ＦＰ１８则转变为α－螺旋结构。综合分析Ｔ１４,Ｔ１８和ＴＤＫ三个模型肽的结构性质和稳定性,比较肽链序列和溶剂作用,提出肽链局部优势结构的概念,并据此讨论天花粉蛋白小结构域折叠起始过程。     

NMR法研天花粉蛋白T14肽片段的溶液构象

本文报道用ＨＮＭＲ法测定Ｔ１４肽在ＤＭＳＯ（ＭＳ１４）,Ｈ２Ｏ（ＨＯ１４）,５０％甲醇（ＭＥ１４）和５０％六氟异丙醇（ＦＰ１４）中的溶液构象。通过ＮＯＥ效应,偶合常数,Ｈ／Ｄ交换速率表征和定位二级结构和疏水域,计算两面角φ和螺旋形成几率。结果表明序列Ｓｅｒ９－Ｉｌｅ１７在ＨＯ１４中较为有序,存在强疏水作用,推测是类似螺旋样的亚稳结构;而在ＤＭＳＯ中序列ＳＡＬＳＫＱ存在形成α－螺旋结构的可能性,且六     

天花粉蛋白小结构域N端同源片段的溶液构象,T18肽的圆二色性…

应用圆二色性,内源荧光和疏水荧光探针法进一步研究Ｔ１８肽的溶液构象及其相互转化,发现Ｔ１８肽在水溶液中为β折叠结构,且在高浓度（〉１ｍｇ／ｍｌ）时形成疏水聚合物,Ｌｙｓ１５和Ｉｌｅ３－Ｉｌｅ４是形成β折叠疏水簇的关键因素,并讨论了蛋白质链和溶剂环境对肽段二级结构的调制作用。     

大鼠TCF—a修饰16肽的溶液构象

已知大鼠ＴＧＦ－ａ的抗原部位于Ｃ环,且大鼠的ＴＧＦ－ａ（３４－４３）和ＴＧＦａ（４４－５０）均有较强的活性以转化正常细胞。为了提示其结构与功能关系,合成了大鼠ＴＧＦ－ａ修饰１６肽。在前文用二维核磁共振技术归属质子谱并验证其一级结构的基础上,本文测定了不同混合时间的二维ＮＯＥＳＹ谱。根据所得的数据原始斜率法求出距离约束。通过约束分子动力学计算定出该分子溶液构象。其中还用ＤＱＦ－ＣＯＳＹ的数据求出二面     

大鼠TGF－α修饰16肽的溶液构象

已知大鼠Ｔ０Ｆ－α的抗原部位干Ｃ环,且大鼠的ＴＧＦ—α（３４－４３）和ＴＧＦ－α（４４－５０）均有较强的活性以转化正常细胞。为了揭示其结构与功能关系,合成了大鼠ＴＧＦ－α修饰１６肽。在前文用二维核磁共振技术归属质子谱并验证其一级结构的基础上,本文测定了不同混合时间的二维ＮＯＥＳＹ谱。根据所得的数据因原始斜率法求出距离约束。通过约束分子动力学计算定出该分子的溶液构象。其中还用ＤＱＦ－ＣＯＳＹ的数据求出二面角作为决定溶液构象的参考。     

天花粉蛋白小结构域N端TCS182—200同源片段的构象研究

以天花粉蛋白小结构域Ｎ端ＴＣＳ１８２－２００同源片段序列为基础,设计Ｔ１４,Ｔ１８和ＴＤＫ３个模型肽。本文分析了模型肽的肽链柔性和侧链两亲性,预测二级结构形成势,并通过多肽固相合成和圆二色性研究模型肽的溶液二级结构,比较理论预测和实测结果。在水溶液中,Ｔ１８为β－折叠,ＴＤＫ含有一定量α－螺旋;而Ｔ１４基本上为无规卷曲,但在碱性条件下有类似螺肇的亚稳结构存在。     

蛋白质溶液构象的研究方法

蛋白质的结构决定其功能。研究蛋白质溶液构象的手段日新月异,文章介绍了近年来研究蛋白质在溶液中三级结构、二级结构和基团微环境的常用手段。     

天花粉蛋白小结构域N端同源片段的溶液构象：T18肽的圆二色性和荧光研究

应用圆二色性,内源荧光和疏水荧光探针法进一步研究Ｔｌ８肽的溶液构象及其相互转化。发现Ｔ１８肽在水溶液中为β折叠结构,且在高浓度（＞１ｍｇ／ｍｌ）时形成疏水聚合物;Ｌｙｓ１５和Ｉｌｅ３－Ｉｌｅ４是形成β折叠疏水簇的关键因素。并讨论了蛋白质肽链和溶剂环境对肽段二级结构的调制作用。     

Intramolecular Conformation of Puromycin in Solution As Studied by Proton Magnetic Resonance

Abstract

The intramolecular conformation of puromycin, a broad spectrum antiobiotic, in solution has been investigated by proton magnetic resonance (PMR) spectroscopy. A comparison of the proton chemical shift and proton-proton coupling constant data of puromycin with puromycin aminonucleoside suggests that puromycin in solution exists as an equilibrium blend of extended and folded conformers. These folded conformers are the result of flexibility around the C^α-C^β bond of the aminoacyl segment of puromycin. One of the folded conformers predicted by PMR is in excellent agreement with the x-ray data.     

Prion Protein-Detergent Micelle Interactions Studied by NMR in Solution

Cellular prion proteins, PrP^C, carrying the amino acid substitutions P102L, P105L, or A117V, which confer increased susceptibility to human transmissible spongiform encephalopathies, are known to form structures that include transmembrane polypeptide segments. Herein, we investigated the interactions between dodecylphosphocholine micelles and the polypeptide fragments 90–231 of the recombinant mouse PrP variants carrying the amino acid replacements P102L, P105L, A117V, A113V/A115V/A118V, K110I/H111I, M129V, P105L/M129V, and A117V/M129V. Wild-type mPrP-(90–231) and mPrP[M129V]-(91–231) showed only weak interactions with dodecylphosphocholine micelles in aqueous solution at pH 7.0, whereas discrete interaction sites within the polypeptide segment 102–127 were identified for all other aforementioned mPrP variants by NMR chemical shift mapping. These model studies thus provide evidence that amino acid substitutions within the polypeptide segment 102–127 affect the interactions of PrP^C with membranous structures, which might in turn modulate the physiological function of the protein in health and disease.Transmissible spongiform encephalopathies (TSEs),² such as Creutzfeldt-Jakob disease and the Gerstmann-Sträussler-Scheinker syndrome in humans, are accompanied by the appearance in the brain of an aggregated “scrapie” isoform of the host-encoded prion protein, PrP^Sc (1–3). The cellular form, PrP^C, consists of an unstructured N-terminal “tail” of residues 23–125 and a globular domain of residues 126–231, and is attached by a C-terminal glycosylphosphatidylinositol (GPI) anchor to the outer plasma membrane. This structure ensures a role of membrane interactions in the physiological function of PrP^C and probably also in the disease-related events leading to TSEs. For example, transgenic mice expressing a prion protein variant lacking the GPI membrane anchor did not develop the typical clinical signs of TSE after inoculation with infectious brain homogenate, although significant amounts of PrP^Sc accumulated in the brain (4). This finding led to the conclusion that membrane-association of PrP^C is necessary for the development of a TSE. Independent evidence for the importance of membrane interactions for the onset of prion diseases was derived from cell-free conversion assays and cell culture experiments (5, 6).Data have also been presented that indicate that in addition to the normal form with the C terminus linked to a GPI anchor and the C-terminal domain located on the cell surface, PrP^C can adopt two different transmembrane topologies, ^CtmPrP and ^NtmPrP, which have the C-terminal polypeptide segment located in the lumen of the endoplasmic reticulum (^CtmPrP) or in the cytoplasm (^NtmPrP) (7–9). The population of the ^CtmPrP variant is <10% of the total wild-type prion protein present during cellular biosynthesis but is increased to 20–30% for the pathogenic mutations P102L, P105L, and A117V of human PrP and the designed variant mouse PrPs obtained with the amino acid exchanges A113V/A115V/A118V and K110I/H111I (10–13). The population of ^CtmPrP was further increased when an additional mutation, L9R, was present in the N-terminal signal sequence (14), so that ∼50% of the PrP was synthesized as the ^CtmPrP variant in granule neurons obtained from transgenic mice expressing a prion protein construct carrying the four amino acid replacements L9R, A113V, A115V, and A118V (15). Quite generally, an increase in the population of ^CtmPrP was also shown to be associated with severe neurodegeneration in transgenic mice, and it has been suggested that ^CtmPrP may be the proximate cause of neuronal death in certain prion disorders (10, 11, 15).In vitro studies on interactions of full-length and N-terminally truncated forms of recombinant PrP showed that acidic membranes caused the N-terminal part of the protein to become more structured, whereas the C-terminal domain was destabilized (16–19). Furthermore, zwitterionic gel-phase dipalmitoylphosphatidylcholine or raft-like membranes were shown to induce increased α-helical structure in recombinant Syrian hamster PrP-(90–231) at pH 7.0 (18, 19). Membrane interactions of polypeptides representing sequence motifs found in the prion protein have also been studied (20–23).In this report we describe investigations of PrP interactions with a membrane mimetic and focus on the mutations P102L, P105L, and A117V, which have been linked with familial Gerstmann-Sträussler-Scheinker syndrome in humans (2, 24, 25). Our interest in these variant proteins is related to open questions about the mechanisms by which pathogenic mutations predispose humans for prion diseases. We studied the interactions of a recombinant wild-type mouse prion protein fragment, mPrP-(90–231), and the variants mPrP[P102L]-(91–231), mPrP[P105L]-(91–231), mPrP[A117V]-(90–231), mPrP[A113V,A115V,A118V]-(90–231), and mPrP[K110I,H111I]-(90–231). For these studies, we used the N-terminally truncated protein composed of residues 90–231. This region contains the transmembrane segment, all known disease-associated point mutations, the entire polypeptide fragment with proteinase K-resistance in PrP^Sc, which is also sufficient to transmit disease (1, 25, 26). The amino acid substitutions in these variant PrPs are located either within a hydrophobic stretch of residues 112–127, which is highly conserved in mammalian PrPs (27, 28), or in the positively charged segment of residues 95–111 (Fig. 1, B and C). We also included the M129V polymorphism into this study, which was reported to have a significant influence on the susceptibility of humans to prion diseases and on the disease phenotype. For example, the mutations P105L and A117V are only pathogenic in the presence of valine at position 129 (2, 24). The zwitterionic detergent dodecylphosphocholine (DPC, Fig. 1A) was used as a biomembrane mimetic model system, and NMR spectroscopy was employed to screen for protein-detergent micelle interactions, and for the structural characterization of the various prion protein constructs interacting with the detergent micelles.Open in a separate windowFIGURE 1.Detergent and proteins used in this study. A, zwitterionic form of DPC. B, schematic diagram of the mPrP-(90–231) polypeptide indicating the locations of the regular secondary structures, i.e. three α-helices and two strands of an antiparallel β-sheet, a “positively charged cluster” (CC) of amino acid residues in positions 95–111, and a “hydrophobic polypeptide segment” (HPS) comprising residues 112–127. C, amino acid sequence alignment of residues 90–135 for wild-type mPrP-(90–231) and the protein variants studied in this paper, where for each variant mPrP the amino acid replacements are given and identical residues are indicated by dots; the numbering is according to Schätzl et al. (27).     

Proliferating Cell Nuclear Antigen (PCNA) Interactions in Solution Studied by NMR

PCNA is an essential factor for DNA replication and repair. It forms a ring shaped structure of 86 kDa by the symmetric association of three identical protomers. The ring encircles the DNA and acts as a docking platform for other proteins, most of them containing the PCNA Interaction Protein sequence (PIP-box). We have used NMR to characterize the interactions of PCNA with several other proteins and fragments in solution. The binding of the PIP-box peptide of the cell cycle inhibitor p21 to PCNA is consistent with the crystal structure of the complex. A shorter p21 peptide binds with reduced affinity but retains most of the molecular recognition determinants. However the binding of the corresponding peptide of the tumor suppressor ING1 is extremely weak, indicating that slight deviations from the consensus PIP-box sequence dramatically reduce the affinity for PCNA, in contrast with a proposed less stringent PIP-box sequence requirement. We could not detect any binding between PCNA and the MCL-1 or the CDK2 protein, reported to interact with PCNA in biochemical assays. This suggests that they do not bind directly to PCNA, or they do but very weakly, with additional unidentified factors stabilizing the interactions in the cell. Backbone dynamics measurements show three PCNA regions with high relative flexibility, including the interdomain connector loop (IDCL) and the C-terminus, both of them involved in the interaction with the PIP-box. Our work provides the basis for high resolution studies of direct ligand binding to PCNA in solution.     

The Solution Structure of Yeast tRNAPhe as Studied by Nuclear Overhauser Effects in NMR

Abstract

Recently, the imino proton spectrum of yeast tRNA^Phe has been assigned by means of the application of the nuclear Overhauser effect (NOE). In the present paper it will be shown that even for tRNA (MW 28000) connectivities between the imino proton spins can be observed using two-dimensional NOE spectroscopy. In this way the imino proton resonances of the D-stem region are assigned. The results are discussed in relation to those obtained by the classical one-dimensional nuclear Overhauser effect. It turns out that in 2D-NOE experiments connectivities from overlapping resonances can be observed which cannot be determined by one-dimensional Overhauser experiments. Moreover, the total assignment of the imino proton spectrum of yeast tRNA^Phe is used to relate the three-dimensional crystal structure of the tRNA to its solution structure. It is shown that the principle elements of the X-ray structure, i.e. the hydrogen bonding network and the stacking of the stems upon one another, are also found in solution. This is true for the presence as well as for the absence of magnesium ions. However, in absence of magnesium ions the tRNA structure appears to differ in details from that in the presence of magnesium ions. Finally, the influence of the elongation factor Tu from B.stearothermophilus on the tRNA structure is discussed.     

The Principal Neutralizing Determinant of HIV-1IIIB: Conformation of the Peptide Bound to a Neutralizing Antibody Studied by 2D-NMR

Summary RP135 is a 24-residue peptide corresponding to the principal neutralizing determinant of the envelope glycoprotein gp120 of the human immunodeficiency virus type 1. We have studied the conformation of RP135 in complex with a neutralizing antibody 0.5β raised against gp120 by 2D NMR spectroscopy. The antigenic determinant recognized by this antibody was mapped using a combination of HOHAHA and ROESY measurements, in which resonances of the Fab and the tightly bound peptide residues are eliminated and the mobile residues of the bound peptide are sequentially assigned. We found that residues Ser⁶-Thr¹⁹ are part of the epitope, while Lys⁵ and Ile²⁰ are at its boundaries. Difference spectroscopy was applied to study the conformation of the bound peptide representing the epitope within the 52 kDa of the Fab complex. Specific residues of the peptide were deuterated or replaced and the difference between the NOESY spectrum of the complex with the unlabeled residue and the NOESY spectrum of the complex with the modified residue revealed the interactions of the labeled residue both within the peptide and with the Fab fragment. A total of 122 distance restraints derived from the difference spectra enabled the calculation of the structure of the bound peptide. The peptide forms a 10-residue loop, while the two segments flanking this loop interact extensively with each other and possibly form anti-parallel β-strands. The loop conformation could be observed due to the unusual large size (17 residues) of the antigenic determinant recognized by 0.5β.     

天花粉蛋白胰酶肽图谱的毛细管区带电泳法分析

目的:以天花粉蛋白胰蛋白酶解肽段为测定对象,用毛细管区带电泳法(CZE)研究天花粉蛋白的肽图谱分离条件。方法:采用未涂层石英毛细管(长50cm,内径75μm,有效长度42cm),以50mmol/L磷酸盐和150mmol/L三氟乙酸溶液为运行缓冲液,在25℃、pH2.0和压力为3447.4Pa(×10s)的条件下进样,以12kV恒压电泳分离,检测波长214nm。结果:运用CZE也能较好地对天花粉蛋白进行肽图谱分离,在缓冲体系中加入离子对试剂三氟乙酸,可极大地改善多肽的峰形和分辨率;同时运用反相高效液相色谱(RP-HPLC)技术,也很好地鉴定了部分肽段在CZE和RP-HPLC肽图谱中的对应关系。结论:与传统的RP-HPLC分析天然或重组蛋白肽图谱相比,CZE也不失为一种鉴定蛋白肽图谱的有效、快速和简单的方法。     

mHCN1通道孔隙多肽溶液构象的核磁共振研究

通过分析在 5 0 ? TFE 5 0 %H2 O溶液中采集的WET TOCSY、WET NOESY等二维核磁共振波谱 ,确定了mHCN1通道孔隙多肽氨基酸残基的自旋系统 ;通过解析NOESY谱中的NOE相关点 ,完成了对其序列以及主链和侧链质子的全部归属。利用NOE信息进行了结构计算 ,得到其三维结构。三维结构显示mHCN1通道孔隙多肽中存在一段α螺旋。其核磁共振研究结果为更深入研究选择性离子通道的机制提供了良好的基础。