WD-重复蛋白

 WD基元又称Trp-ASP或WD40,由40个左右的氨基酸残基组成,具有保守的GH和WD序列.WD基元存在于很多具有调控功能的蛋白质中,介导蛋白质之间的相互作用,在信号转导、蛋白运输、染色体修饰、转录或RNA加工等过程中具有重要作用.WD重复蛋白(WD-repeat protein)是含有多个保守的WD基元的蛋白质.近年发现,WD-repeat基因突变与人的几种疾病相关.本文对真核生物WD-重复蛋白的研究进展进行了综述,阐明了WD 重复蛋白的β-propeller结构特征及其作用机制,并对WD-重复蛋白的未来研究方向进行展望.     

3大种群蛋白质内部重复片段组成规律的比较研究

20世纪70年代,Ohno提出了功能蛋白的起源理论,认为寡肽片段的周期性重复是蛋白质起源的一种方式。蛋白质内部重复片段在蛋白质序列进化的过程中具有重要意义。选取原核生物、古细菌、真核生物的8个代表物种,设计了新的蛋白质内部重复片段的提取方法,并用矩阵的方式对重复片段的类型及其出现的频率进行形象地展现,既保留了重复片段的序列特征又可进行全局性的统计描述。分析表明：真核生物高频率的使用简单重复序列;真细菌也具有低频率使用简单重复序列的现象;而古细菌则几乎没有。进一步研究显示,3大种群生物偏向性使用氨基酸构成蛋白质内部重复片段的形为与蛋白质组的氨基酸使用频率紧密相关。其相关系数在真细菌和古细菌中高于0．95,而真核生物略低。真核生物蛋白质组大量使用简单重复片段,以及两者在氨基酸使用上的较低相关性暗示简单重复序列的快速进化是导致真核生物蛋白质组高复杂性的一个关键因素。     

化学药物对与人遗传病相关的DNA重复序列不稳定性的影响

DNA重复序列异常扩增或删除会引起多种人类遗传疾病,目前其不稳定性机制还不清楚。为了探索化学药物对重复序列的作用,采用甲基磺酸乙酯和丝裂霉素C连续多次处理含重复序列质粒的菌体,通过检测重复序列长度的变化,发现两种化学药物在不同程度上可以促使含(GAA)42和(ATTCT)43质粒发生删除,而含(GCCT)18质粒的长度没有发生变化。     

植物色氨酸一天冬氨酸重复序列蛋白响应逆境胁迫的调控作用

干旱、盐渍、低温等逆境胁迫会严重影响植物的正常生长发育,导致植物的许多响应基因被诱导表达,其蛋白质产物能够保护植物免受胁迫的伤害。色氨酸一天冬氨酸重复序列蛋白（wD40蛋自）在植物中广泛存在,参与植物体内众多代谢反应的调控,如花的发育、开花、花青素的生物合成、激素响应、渗透胁迫等。WD40蛋白含有40-60个氨基酸的保守的wD重复序列,其c末端为色氨酸．天冬氨酸（Trp-Asp,WD）,形成一个p螺旋桨（p—propeller）结构,通过调节多蛋白复合体的组装而影响蛋白质与蛋白质、蛋白质与DNA间的相互作用。本文综述植物WD40蛋白响应逆境胁迫的调控作用。     

拟南芥与水稻之间简单重复序列的比较分析

利用Perl,C 语言编写了鉴定和分析简单重复序列的一系列程序,在全基因组水平上分析了拟南芥(ArabidopsisthalianaL.)简单重复序列的分布及简单重复序列和基因的关系。共发现5652个简单重复序列(≥20bp),大约每20.6kb有1个简单重复序列。拟南芥各染色体之间简单重复序列的密度基本一致。拟南芥的27480条编码序列中,只有677条编码序列含有725个简单重复序列,其中的3碱基简单重复序列多数对应的是小的亲水性的氨基酸。在拟南芥和水稻(OryzasativaL.)第4号染色体的高度保守的基因中,简单重复序列却并不保守。通过比较拟南芥和水稻之间简单重复序列的差异,推论出:水稻的全基因组和基因中简单重复序列的密度都比拟南芥大,这可能是水稻基因组序列比拟南芥大的原因之一,水稻基因组中0.21%来自简单重复序列,而拟南芥中只有0.13%;不但不同物种的基因组对简单重复序列的偏好性不同,而且不同物种的基因对简单重复序列的偏好性也不同。在水稻和拟南芥中都发现了一些嵌套性的卫星序列。     

串联重复序列的物种差异及其生物功能

串联重复序列是指1-200个碱基左右的核心重复单位,以头尾相串联的方式重复多次所组成的重 复序列。它广泛存在于真核生物和一些原核生物的基因组中,并表现出种属、碱基组成等的特异性。在基因组 整体水平上,各种优势的重复序列类型不同。即使在同一重复序列类型内部,不同重复拷贝类别(如AT、AC 等)在基因组中的存在也表现出很大的差异。同时,这些重复序列类型和各重复拷贝类别在同一物种的不同染 色体间,以及基因的编码区和非编码区间也表现种属和碱基组成差异。这些差异显示了重复序列起源和进化的 复杂性,可能涉及到多种机制和因素,并与生物功能密切相关。另外,由于重复序列分析软件和统计标准还存 在算法、重复长度、完美性等问题,需要进一步探讨。此外,串联重复序列的自身进化关系、全基因组水平上 的进化地位、在基因组中的生物功能、重复序列数据库建立和应用研究等,将是今后研究的主要课题。     

拟南芥与水稻之间简单重复序列的比较分析

利用Peri,C 语言编写了鉴定和分析简单重复序列的一系列程序,在全基因组水平上分析了拟南芥(Arabidopsisthaliana L.)简单重复序列的分布及简单重复序列和基因的关系.共发现5 652个简单重复序列(≥20bp),大约每20.6kb有1个简单重复序列.拟南芥各染色体之间简单重复序列的密度基本一致.拟南芥的27 480条编码序列中,只有677条编码序列含有725个简单重复序列,其中的3碱基简单重复序列多数对应的是小的亲水性的氨基酸.在拟南芥和水稻(Oryza sativa L.)第4号染色体的高度保守的基因中,简单重复序列却并不保守.通过比较拟南芥和水稻之间简单重复序列的差异,推论出:水稻的全基因组和基因中简单重复序列的密度都比拟南芥大,这可能是水稻基因组序列比拟南芥大的原因之一,水稻基因组中0.21%来自简单重复序列,而拟南芥中只有0.13%;不但不同物种的基因组对简单重复序列的偏好性不同,而且不同物种的基因对简单重复序列的偏好性也不同.在水稻和拟南芥中部发现了一些嵌套性的卫星序列.     

斜纹夜蛾核多角体病毒DNA XbaI 4.0 kb片段锌指蛋白基因及重复序列分析

测定了斜纹夜蛾核多角体病毒 (Spodopteralituranucleopolyhedrovirus,SpltNPV)中山大学分离株基因组DNAXbaI4.0kb片段全序列 ,该片段包括一个锌指蛋白基因及三个区域的DNA重复序列 (SR1、SR2、SR3)。该锌指蛋白基因读码框为 2 196个核苷酸 ,编码 731个氨基酸的蛋白质 ,分子量为 83 .0 9kD ,该蛋白的等电点为 4.6 1。在其 5′非编码区内有一个杆状病毒早期启动子基序GAGT及一个TATA盒 ,在其终止密码的下游有 5个真核生物转录mRNA时poly(A)加尾信号AATAAA。在 2 2 3～ 2 41氨基酸残基之间有一个锌指蛋白基序 ,这一基序属于锌指蛋白基序中的C3HC4类 ,即环指 (Ringfinger)类基序。在 32 3～ 340氨基酸残基区域为一个核定位信号。该蛋白可能为一个高度折叠的蛋白质。在该片段中存在三个DNA重复序列区域 (SR1、SR2、SR3) ,其中SR1与SR3区域存在更大量的重复序列 ,SR1区域其中的一个重复序列长达 41bp ,SR1、SR3重复序列区域可能作为该病毒转录的增强子 ,或者作为DNA复制的起始点。     

核酸序列重复片段的统计分析

对核酸序列编码区的重复片段进行了统计分析。发现不同物种的序列具有近似相等的约化重复长度和次数,研究了重复区内碱基分布的特点,并讨论了此结果可能的生物学涵义。     

斜纹夜蛾核多角体病毒 DNA XbaI 4.0 kb 片段锌指蛋白基因及重复序列分析

测定了斜纹夜蛾核多角体病毒(Spodopteralituranucleopolyhedrovirus,SpltNPV)中山大学分离株基因组DNAXbaI4.0kb片段全序列,该片段包括一个锌指蛋白基因及三个区域的DNA重复序列(SR1、SR2、SR3).该锌指蛋白基因读码框为2196个核苷酸,编码731个氨基酸的蛋白质,分子量为83.09kD,该蛋白的等电点为4.61.在其5′非编码区内有一个杆状病毒早期启动子基序GAGT及一个TATA盒,在其终止密码的下游有5个真核生物转录mRNA时poly(A)加尾信号AATAAA.在223～241氨基酸残基之间有一个锌指蛋白基序,这一基序属于锌指蛋白基序中的C3HC4类,即环指(Ringfinger)类基序.在323～340氨基酸残基区域为一个核定位信号.该蛋白可能为一个高度折叠的蛋白质.在该片段中存在三个DNA重复序列区域(SR1、SR2、SR3),其中SR1与SR3区域存在更大量的重复序列,SR1区域其中的一个重复序列长达41bp,SR1、SR3重复序列区域可能作为该病毒转录的增强子,或者作为DNA复制的起始点.     

Modulation of the multistate folding of designed TPR proteins through intrinsic and extrinsic factors

Tetratricopeptide repeats (TPRs) are a class of all alpha-helical repeat proteins that are comprised of 34-aa helix-turn-helix motifs. These stack together to form nonglobular structures that are stabilized by short-range interactions from residues close in primary sequence. Unlike globular proteins, they have few, if any, long-range nonlocal stabilizing interactions. Several studies on designed TPR proteins have shown that this modular structure is reflected in their folding, that is, modular multistate folding is observed as opposed to two-state folding. Here we show that TPR multistate folding can be suppressed to approximate two-state folding through modulation of intrinsic stability or extrinsic environmental variables. This modulation was investigated by comparing the thermodynamic unfolding under differing buffer regimes of two distinct series of consensus-designed TPR proteins, which possess different intrinsic stabilities. A total of nine proteins of differing sizes and differing consensus TPR motifs were each thermally and chemically denatured and their unfolding monitored using differential scanning calorimetry (DSC) and CD/fluorescence, respectively. Analyses of both the DSC and chemical denaturation data show that reducing the total stability of each protein and repeat units leads to observable two-state unfolding. These data highlight the intimate link between global and intrinsic repeat stability that governs whether folding proceeds by an observably two-state mechanism, or whether partial unfolding yields stable intermediate structures which retain sufficient stability to be populated at equilibrium.     

Mapping the energy landscape of repeat proteins using NMR-detected hydrogen exchange

Repeat proteins contain tandem arrays of a simple structural motif. In contrast to globular proteins, repeat proteins are stabilized only by interactions between residues that are relatively close together in the sequence, with no ”long-range” interactions. Our work focuses on the tetratricopeptide repeat (TPR), a 34 amino acid helix-turn-helix motif found in tandem arrays in many natural proteins. Earlier, we reported the design and characterization of a series of consensus TPR (CTPR) proteins, which are built as arrays of multiple tandem copies of a 34 amino acid consensus sequence. Here, we present the results of extensive hydrogen exchange (HX) studies of the folding-unfolding behavior of two CTPR proteins (CTPR2 and CTPR3). We used HX to detect and characterize partially folded species that are populated at low frequency in the nominally folded state. We show that for both proteins the equilibrium folding-unfolding transition is non-two-state, but sequential, with the outermost helices showing a significantly higher probability than inner helices of being unfolded. We show that the experimentally observed unfolding behavior is consistent with the predictions of a simple Ising model, in which individual helices are treated as ”spin-equivalents”. The results that we present have general implications for our understanding of the thermodynamic properties of repeat proteins.     

Comparison of the backbone dynamics of a natural and a consensus designed 3-TPR domain

The tetratricopeptide repeat (TPR) is a 34-amino acid helix-turn-helix motif that occurs in tandem arrays in numerous proteins. Here we compare the backbone dynamics of a natural 3-repeat TPR domain, from the protein UBP, with the behavior of a designed protein CTPR3, which consists of three identical consensus TPR units. Although the three tandem TPR repeats in both CTPR3 and UBP behave as a single unit, with no evidence of independent repeat motions, the data indicate that certain positions in UBP are significantly more flexible than are the corresponding positions in CTPR3. Most of the dynamical changes occur at or adjacent to positions that are involved in intra-repeat packing interactions. These observations lead us to suggest that the three-TPR domain of UBP does not incorporate optimized packing, compared to that seen in the idealized CTPR. The natural TPR domain is not only less stable overall than CTPR3, but also presents increased local flexibility at the positions where the sequences differs from the conserved consensus.     

Repeat motions and backbone flexibility in designed proteins with different numbers of identical consensus tetratricopeptide repeats

The tetratricopeptide repeat (TPR) is a 34-residue helix-turn-helix motif that occurs as three or more tandem repeats in a wide variety of proteins. We have determined the repeat motions and backbone fluctuations of proteins containing two or three consensus TPR repeats (CTPR2 and CPTR3, respectively) using 15N NMR relaxation measurements. Rotational diffusion tensors calculated from these data for each repeat within each TPR protein indicate that there is a high degree of motional correlation between different repeats in the same protein. This is consistent with the prevailing view that repeat proteins, such as CTPR2 and CTPR3, behave as single cooperatively folded domains. The internal motions of backbone NH groups were determined using the Lipari-Szabo model-free formalism. For most residues, there was a clear separation between the influence of internal motion and the influence of global rotational tumbling on the observed magnetic relaxation. The local internal motions are highly restricted in most of the helical elements, with slightly greater flexibility in the linker elements. Comparisons between CTPR2 and CTPR3 indicate that an addition of a TPR repeat to the C-terminus (before the solvation helix) of CTPR2 slightly reduces the flexibility of the preceding helix.     

Calorimetric study of a series of designed repeat proteins: modular structure and modular folding

Repeat proteins comprise tandem arrays of a small structural motif. Their structure is defined and stabilized by interactions between residues that are close in the primary sequence. Several studies have investigated whether their structural modularity translates into modular thermodynamic properties. Tetratricopeptide repeat proteins (TPRs) are a class in which the repeated unit is a 34 amino acid helix-turn-helix motif. In this work, we use differential scanning calorimetry (DSC) to study the equilibrium stability of a series of TPR proteins with different numbers of an identical consensus repeat, from 2 to 20, CTPRa2 to CTPRa20. The DSC data provides direct evidence that the folding/unfolding transition of CTPR proteins does not fit a two-state folding model. Our results confirm and expand earlier studies on TPR proteins, which showed that apparent two-state unfolding curves are better fit by linear statistical mechanics models: 1D Ising models in which each repeat is treated as an independent folding unit.     

Cloning and sequencing of a gene encoding a new member of the tetratricopeptide protein family from magnetosomes of Magnetospirillum magnetotacticum

A gene encoding the 22-kDa protein (MAM22) which was localized in the magnetosomes isolated from the magnetotactic bacterium, Magnetospirillum magnetotacticum, was cloned and sequenced. MAM22 was composed of 220 amino acids (aa) with a molecular weight of 24 186 Da. The deduced aa sequence exhibited significant homology with a number of proteins that belong to the tetratricopeptide repeat (TPR) protein family, including mitochondrial protein import receptors and peroxisomal protein import receptors. The presence of three repeats of a degenerate 34-aa consensus sequence, suggest that MAM22 localized in magnetosome membranes may interact with the cytoplasmic proteins containing similar TPR motifs.     

Crystal structure of YrrB: a TPR protein with an unusual peptide-binding site

YrrB is a hypothetical protein containing a tetratricopeptide repeat (TPR) domain from a Gram-positive bacterium, Bacillus subtilis. We determined YrrB structure in the C2 space group to 2.5A resolution, which is the first TPR structure of the Gram-positive bacterium B. subtilis. In contrast to other known TPR structures, the concave surface of the YrrB TPR domain is composed of the putative peptide-binding pocket lined with positively-charged residues. This unique charge distribution reveals that YrrB can interact with partner proteins via an unusual TPR-mediated interaction mode, compared to that of other TPR-containing structures. Functional annotation using genomics analysis suggested that YrrB may be an interacting mediator in the complex formation among RNA sulfuration components. No proteins containing a TPR domain have been identified in the biosynthesis of sulfur-containing biomolecules. Thus, YrrB could play a new role as a connecting module among those proteins in the conserved gene cluster for RNA sulfuration.     

Evidence that the kinesin light chain domain contains tetratricopeptide repeat units

Homology models were built for various length sequences of the kinesin-1 light chain (KLC) domain of Drosophila melanogaster and subjected to 200 ns of all-atom molecular dynamics. We also cloned, expressed and characterized these regions spectroscopically. Results confirm that KLC contains tetratricopeptide repeat units; a regular array of repeating 34-residue helix-loop-helix monomers. Experimental and computational evidence is provided confirming the stability and overall helicity of individual TPR repeats as well as individual TPR units incorporated into a multi-TPR structure.     

The Assembly and Intermolecular Properties of the Hsp70-Tomm34-Hsp90 Molecular Chaperone Complex

Maintenance of protein homeostasis by molecular chaperones Hsp70 and Hsp90 requires their spatial and functional coordination. The cooperation of Hsp70 and Hsp90 is influenced by their interaction with the network of co-chaperone proteins, some of which contain tetratricopeptide repeat (TPR) domains. Critical to these interactions are TPR domains that target co-chaperone binding to the EEVD-COOH motif that terminates Hsp70/Hsp90. Recently, the two-TPR domain-containing protein, Tomm34, was reported to bind both Hsp70 and Hsp90. Here we characterize the structural basis of Tomm34-Hsp70/Hsp90 interactions. Using multiple methods, including pull-down assays, fluorescence polarization, hydrogen/deuterium exchange, and site-directed mutagenesis, we defined the binding activities and specificities of Tomm34 TPR domains toward Hsp70 and Hsp90. We found that Tomm34 TPR1 domain specifically binds Hsp70. This interaction is partly mediated by a non-canonical TPR1 two-carboxylate clamp and is strengthened by so far unidentified additional intermolecular contacts. The two-carboxylate clamp of the isolated TPR2 domain has affinity for both chaperones, but as part of the full-length Tomm34 protein, the TPR2 domain binds specifically Hsp90. These binding properties of Tomm34 TPR domains thus enable simultaneous binding of Hsp70 and Hsp90. Importantly, we provide evidence for the existence of an Hsp70-Tomm34-Hsp90 tripartite complex. In addition, we defined the basic conformational demands of the Tomm34-Hsp90 interaction. These results suggest that Tomm34 represents a novel scaffolding co-chaperone of Hsp70 and Hsp90, which may facilitate Hsp70/Hsp90 cooperation during protein folding.