基于结构的单绕蛋白聚类图构建与分析

蛋白质分子进化规律研究是分子进化研究的重点,对揭示生命起源与进化机制有重要意义。本文对已知空间结构及物种信息的单绕蛋白,利用结构比对信息,构建了不同层次单绕样本系统聚类图。分析发现:功能相似蛋白存在明显聚集现象,同一超家族样本基本聚在一个大支中,同一家族样本集中在所属超家族下的小支中,功能约束下单绕样本聚类图与物种进化图有较好对应关系。结果表明:单绕蛋白的结构演化反映了蛋白质功能的约束,特定功能单绕样本的结构差异具有种属特异性,结构演化包含了物种进化信息。     

正痘病毒属成员血凝素分子的结构及分子进化途径的分析

利用DNA聚合酶链式反应(PCR)及其它分子生物学技术克隆了23株包括所有正痘病毒属成员在内的病毒血凝素(HA)基因.核苷酸序列分析及结构与功能的研究发现HA分子具有与细胞粘着分子超家族成员(CAM)相似的结构,其生物学功能主要与结构中的IgG结构域和广泛的O型糖基化结构有关.另外,以HA分子基因的核苷酸和其氨基酸序列为比较指标,首次在基因水平对正痘病毒的起源和进化途径以及病毒间的抗原相关性等进行了分析.基因的分子进化树和蛋白质系统分类树的演段揭示了病毒在宿主选择压力作用下的自然进化途径及相互间的亲缘关系,为进一步阐明正痘病毒的进化过程和控制与预防该类病毒性疾病的流行提供了有价值的依据.     

分子绝对进化速率与物种分歧时间之间的定量关系

通过对美国国家生物技术信息中心数据库Gen Bank提供的一些蛋白质和核苷酸序列进行比对和分析,发现生物分子绝对进化速率k与进化时间或物种分歧时间t之间存在下列定量关系:lnk=-Ea/Rt+lnK0,式中Ea为位点突变活化能,k0为分子极限绝对进化速率,R为常数,并对其生物学意义进行了初步的探讨;数据分析还揭示出物种的分子极限绝对进化速率与进化时间或物种分歧时间之间也服从相似的定量公式,也就是说生物分子进化过程可能同时受到序列位点突变和控制物种分子极限绝对进化速率进化的两个"分子钟"作用,即存在"双重分子钟"现象。     

基于全基因组结构域信息的进化树构建

重建生物进化树一直以来都是进化生物学家的梦想。大量物种全基因组的测序使得我们可以从全基因组水平上构建进化树,来研究各个物种之间的进化关系。本文采用2种统计方法和3种距离计算方法,在全基因组水平上建立基于蛋白质结构的进化树。选取93个物种的全基因组作为分析对象,涵盖了3个超界:真核生物,细菌和古细菌。而结果也正确地将这些物种分为三个大类,每个大分支内部的物种聚类情况也基本和这些物种的形态学分类相吻合。并将这些方法的聚类结果与物种分类的结果相比较,得出丰度的统计方法和基于两向量夹角的距离计算方法这种组合在构建进化树上比其他组合更好。     

DNA分子进化的研究基础和策略

从研究方法和技术手段等方面讨论了分子进化研究上的一些重大问题．阐述了基因的基本结构及DNA分子的进化方式：净化选择、中性进化和分化选择。探讨了利用DNA分子进化数据构建系统树的原理,评价了NJ、UPGMAM、MP和ML4种算法在构建进化树时的合理性与不足,以及进化树可靠性检验的方法,并对未来分子进化生物学的发展加以展望。     

细胞因子受体超家族的结构保守性及生物学意义

细胞因子受体超家族是目前数量最大的受体家族,其成员在序列与空间结构上都有一定的保守性,并存在着共用链现象,说明此超家族各成员可能从同一始祖基因进化而来,研究其结构保守性,对于寻找此超家族新的成员,进行同源蛋白质结构预测,探讨其信号转导机制,都有重要意义。     

肌动蛋白与真核生物的进化

以肌动蛋白氨基酸取代与真核生物进化年代呈线性关系为依据，收集原生生物界，真菌界，植物界和动物界等四界７４种生物的１２８个肌动蛋白序列，通过对其氨基酸序列同源性进行比较，制作出肌动蛋白的分子进化树，并依此进化树从分子水平对真核生物的进化进行一些探讨，从总体上看，肌动蛋白分子进化树较地地反映了真核生物间的进化关系，为确定某些生物的进化位置及进化关系提供了分子证据。     

脊椎动物血浆蛋白质的进化

分子生物学的迅猛发展,使我们有可能从分子水平来探讨生物进化这一经典命题。分子进化遂成为进化生物学中的一个新的研究领域。脊椎动物血浆中有数百种蛋白质,依据其一级结构的类似性可划分为仅仅几个家族。蛋白质的进化主要涉及到基因复制(包括加倍)和外显子改组。对不同种属同一种蛋白质的氨基酸排列顺序的比较,可以给出一些有关蛋白质进化的知识。这方面业已取得的成就极大地推进了进化生物学的发展。     

利用分子进化树计算蛋白质的特异进化速率

本文提出了一种计算蛋白质绝对进化距离和进化速率的方法,它根据现有同源蛋白质的序列构建分子进化树,并推断进化过程中各结点处的共同祖先序列,根据某成员与某结点处共同祖先序列的氨基酸差异百分率,计算该蛋白质序列的特异进化距离和进化速率。比较我们的算法和Ｄａｙｈｏｆｆ等的模拟统计方法表明,我们的算法在一定范围内是正确的。结合计算哺乳动物红细胞生成素的进化速率,讨论了本算法在分子进化研究中的应用。     

哺乳动物朊蛋白基因序列变异及其系统发育意义

以朊蛋白基因(PRNP)为研究对象,从GenBank中选取代表哺乳动物的17目61属共84个物种PRNP的编码区序列,分析了该基因的结构及其在不同层次分类阶元间的进化关系.发现由于在基因内序列重复区存在插入或缺失,PRNP的编码区长度在哺乳动物不同目的物种间存在差异.在终止密码子的使用上不同目的物种之间存在明显的偏好性, TGA和TAG是哺乳动物PRNP最常用的终止密码子,只有奇蹄目的5个种和有袋目袋鼠科的2个种是使用TAA终止.所有84条序列呈现了较高的核苷酸多样性(10.54%).以PRNP为分子标记构建的系统进化树总体上是和以往研究一致的,结果表明PRNP可以应用于哺乳动物较高分类单元的系统进化研究,但对于能否用于种间和种内不能肯定.最后应用系统进化树对尚未有患病报道的哺乳动物的患病可能性进行了预测.     

Structural evolution of the protein kinase-like superfamily

The protein kinase family is large and important, but it is only one family in a larger superfamily of homologous kinases that phosphorylate a variety of substrates and play important roles in all three superkingdoms of life. We used a carefully constructed structural alignment of selected kinases as the basis for a study of the structural evolution of the protein kinase-like superfamily. The comparison of structures revealed a "universal core" domain consisting only of regions required for ATP binding and the phosphotransfer reaction. Remarkably, even within the universal core some kinase structures display notable changes, while still retaining essential activity. Hence, the protein kinase-like superfamily has undergone substantial structural and sequence revision over long evolutionary timescales. We constructed a phylogenetic tree for the superfamily using a novel approach that allowed for the combination of sequence and structure information into a unified quantitative analysis. When considered against the backdrop of species distribution and other metrics, our tree provides a compelling scenario for the development of the various kinase families from a shared common ancestor. We propose that most of the so-called "atypical kinases" are not intermittently derived from protein kinases, but rather diverged early in evolution to form a distinct phyletic group. Within the atypical kinases, the aminoglycoside and choline kinase families appear to share the closest relationship. These two families in turn appear to be the most closely related to the protein kinase family. In addition, our analysis suggests that the actin-fragmin kinase, an atypical protein kinase, is more closely related to the phosphoinositide-3 kinase family than to the protein kinase family. The two most divergent families, alpha-kinases and phosphatidylinositol phosphate kinases (PIPKs), appear to have distinct evolutionary histories. While the PIPKs probably have an evolutionary relationship with the rest of the kinase superfamily, the relationship appears to be very distant (and perhaps indirect). Conversely, the alpha-kinases appear to be an exception to the scenario of early divergence for the atypical kinases: they apparently arose relatively recently in eukaryotes. We present possible scenarios for the derivation of the alpha-kinases from an extant kinase fold.     

Structural Evolution of the Protein Kinase–Like Superfamily

The protein kinase family is large and important, but it is only one family in a larger superfamily of homologous kinases that phosphorylate a variety of substrates and play important roles in all three superkingdoms of life. We used a carefully constructed structural alignment of selected kinases as the basis for a study of the structural evolution of the protein kinase–like superfamily. The comparison of structures revealed a “universal core” domain consisting only of regions required for ATP binding and the phosphotransfer reaction. Remarkably, even within the universal core some kinase structures display notable changes, while still retaining essential activity. Hence, the protein kinase–like superfamily has undergone substantial structural and sequence revision over long evolutionary timescales. We constructed a phylogenetic tree for the superfamily using a novel approach that allowed for the combination of sequence and structure information into a unified quantitative analysis. When considered against the backdrop of species distribution and other metrics, our tree provides a compelling scenario for the development of the various kinase families from a shared common ancestor. We propose that most of the so-called “atypical kinases” are not intermittently derived from protein kinases, but rather diverged early in evolution to form a distinct phyletic group. Within the atypical kinases, the aminoglycoside and choline kinase families appear to share the closest relationship. These two families in turn appear to be the most closely related to the protein kinase family. In addition, our analysis suggests that the actin-fragmin kinase, an atypical protein kinase, is more closely related to the phosphoinositide-3 kinase family than to the protein kinase family. The two most divergent families, α-kinases and phosphatidylinositol phosphate kinases (PIPKs), appear to have distinct evolutionary histories. While the PIPKs probably have an evolutionary relationship with the rest of the kinase superfamily, the relationship appears to be very distant (and perhaps indirect). Conversely, the α-kinases appear to be an exception to the scenario of early divergence for the atypical kinases: they apparently arose relatively recently in eukaryotes. We present possible scenarios for the derivation of the α-kinases from an extant kinase fold.     

The Evolution of Hexamerins and the Phylogeny of Insects

The evolutionary relationships among arthropod hemocyanins and insect hexamerins were investigated. A multiple sequence alignment of 12 hemocyanin and 31 hexamerin subunits was constructed and used for studying sequence conservation and protein phylogeny. Although hexamerins and hemocyanins belong to a highly divergent protein superfamily and only 18 amino acid positions are identical in all the sequences, the core structures of the three protein domains are well conserved. Under the assumption of maximum parsimony, a phylogenetic tree was obtained that matches perfectly the assumed phylogeny of the insect orders. An interesting common clade of the hymenopteran and coleopteran hexamerins was observed. In most insect orders, several paralogous hexamerin subclasses were identified that diversified after the splitting of the major insect orders. The dipteran arylphorin/LSP-1-like hexamerins were subject to closer examination, demonstrating hexamerin gene amplification and gene loss in the brachyceran Diptera. The hexamerin receptors, which belong to the hexamerin/hemocyanin superfamily, diverged early in insect evolution, before the radiation of the winged insects. After the elimination of some rapidly or slowly evolving sequences, a linearized phylogenetic tree of the hexamerins was constructed under the assumption of a molecular clock. The inferred time scale of hexamerin evolution, which dates back to the Carboniferous, agrees with the available paleontological data and reveals some previously unknown divergence times among and within the insect orders. Received: 4 August 1997 / Accepted: 29 October 1997     

Characterization of Tannase Protein Sequences of Bacteria and Fungi: An In Silico Study

The tannase protein sequences of 149 bacteria and 36 fungi were retrieved from NCBI database. Among them only 77 bacterial and 31 fungal tannase sequences were taken which have different amino acid compositions. These sequences were analysed for different physical and chemical properties, superfamily search, multiple sequence alignment, phylogenetic tree construction and motif finding to find out the functional motif and the evolutionary relationship among them. The superfamily search for these tannase exposed the occurrence of proline iminopeptidase-like, biotin biosynthesis protein BioH, O-acetyltransferase, carboxylesterase/thioesterase 1, carbon–carbon bond hydrolase, haloperoxidase, prolyl oligopeptidase, C-terminal domain and mycobacterial antigens families and alpha/beta hydrolase superfamily. Some bacterial and fungal sequence showed similarity with different families individually. The multiple sequence alignment of these tannase protein sequences showed conserved regions at different stretches with maximum homology from amino acid residues 389–469 and 482–523 which could be used for designing degenerate primers or probes specific for tannase producing bacterial and fungal species. Phylogenetic tree showed two different clusters; one has only bacteria and another have both fungi and bacteria showing some relationship between these different genera. Although in second cluster near about all fungal species were found together in a corner which indicates the sequence level similarity among fungal genera. The distributions of fourteen motifs analysis revealed Motif 1 with a signature amino acid sequence of 29 amino acids, i.e. GCSTGGREALKQAQRWPHDYDGIIANNPA, was uniformly observed in 83.3 % of studied tannase sequences representing its participation with the structure and enzymatic function.     

The origin and evolution of protein superfamilies.

The organization of proteins into superfamilies based primarily on their sequences is introduced: examples are given of the methods used to cluster the related sequences and to elucidate the evolutionary history of the corresponding genes within each superfamily. Within the framework of this organization, the amount of sequence information currently and potentially available in all living forms can be discussed. The 116 superfamilies already sampled reflect possibly 10% of the total number. There are related proteins from many species in all of these superfamilies, suggesting that the origin of a new superfamily is rare indeed. The proteins so far sequenced are so rigorously conserved by the evolutionary process that we would expect to recognize as related descendants of any protein found in the ancestral vertebrate. The evolutionary history of the thyrotropin-gonadotropin beta chain superfamily is discussed in detail as an example. Some proteins are so constrained in structure that related forms can be recognized in prokaryotes and eukaryotes. Evolution in these superfamilies can be traced back close to the origin of life itself. From the evolutionary tree of the c-type cytochromes the identity of the prokaryote types involved in the symbiotic origin of mitochondria and chloroplasts begins to emerge.     

Molecular evolution inDrosophila and higher diptera

Summary LHP is a suitable protein for studying evolution in flies (Diptera). This blood protein, which occurs at high concentration late in larval development, was purified to homogeneity from 5 species of Drosophilidae and one species each of Tephritidae and Calliphoridae. Rabbit antisera to the purified LHPs allowed immunological comparisons to be made with the micro-complement fixation technique. Various indirect tests indicated that immunological distance is a reliable estimator of the degree of amino acid sequence difference between LHPs from different species. An evolutionary tree for the 7 LHPs was constructed from the immunological distances with the method of Fitch and Margoliash (1967) to provide the branching order and the method of Chakraborty (1977) to provide the branch lengths. A modified method of tree construction allowed LHPs from 10 additional species to be attached to this tree. The resulting LHP tree for 17 species agrees approximately in branching order with that based on Throckmorton's study of 60 anatomical traits. However, the ratio of anatomical change to LHP change along branches within the tree varies widely, confirming the independence of organismal and molecular evolution. The LHP tree thus provides a new perspective on evolution within and among the families of higher Diptera.     

Combining protein sequence,structure, and dynamics: A novel approach for functional evolution analysis of PAS domain superfamily

PAS domains are widespread in archaea, bacteria, and eukaryota, and play important roles in various functions. In this study, we aim to explore functional evolutionary relationship among proteins in the PAS domain superfamily in view of the sequence‐structure‐dynamics‐function relationship. We collected protein sequences and crystal structure data from RCSB Protein Data Bank of the PAS domain superfamily belonging to three biological functions (nucleotide binding, photoreceptor activity, and transferase activity). Protein sequences were aligned and then used to select sequence‐conserved residues and build phylogenetic tree. Three‐dimensional structure alignment was also applied to obtain structure‐conserved residues. The protein dynamics were analyzed using elastic network model (ENM) and validated by molecular dynamics (MD) simulation. The result showed that the proteins with same function could be grouped by sequence similarity, and proteins in different functional groups displayed statistically significant difference in their vibrational patterns. Interestingly, in all three functional groups, conserved amino acid residues identified by sequence and structure conservation analysis generally have a lower fluctuation than other residues. In addition, the fluctuation of conserved residues in each biological function group was strongly correlated with the corresponding biological function. This research suggested a direct connection in which the protein sequences were related to various functions through structural dynamics. This is a new attempt to delineate functional evolution of proteins using the integrated information of sequence, structure, and dynamics.     

Evolutionarily conserved regions and hydrophobic contacts at the superfamily level: The case of the fold-type I, pyridoxal-5'-phosphate-dependent enzymes

The wealth of biological information provided by structural and genomic projects opens new prospects of understanding life and evolution at the molecular level. In this work, it is shown how computational approaches can be exploited to pinpoint protein structural features that remain invariant upon long evolutionary periods in the fold-type I, PLP-dependent enzymes. A nonredundant set of 23 superposed crystallographic structures belonging to this superfamily was built. Members of this family typically display high-structural conservation despite low-sequence identity. For each structure, a multiple-sequence alignment of orthologous sequences was obtained, and the 23 alignments were merged using the structural information to obtain a comprehensive multiple alignment of 921 sequences of fold-type I enzymes. The structurally conserved regions (SCRs), the evolutionarily conserved residues, and the conserved hydrophobic contacts (CHCs) were extracted from this data set, using both sequence and structural information. The results of this study identified a structural pattern of hydrophobic contacts shared by all of the superfamily members of fold-type I enzymes and involved in native interactions. This profile highlights the presence of a nucleus for this fold, in which residues participating in the most conserved native interactions exhibit preferential evolutionary conservation, that correlates significantly (r = 0.70) with the extent of mean hydrophobic contact value of their apolar fraction.     

动物组织蛋白酶L=like基因家族的进化分析

目的：组织蛋白酶L-like家族是在溶酶体中发现的一类非常重要的半胱氨酸组织蛋白酶。其主要功能为催化各种蛋白质的水解,并通过水解蛋白质参与到许多的生理调节过程当中。根据序列比对分析和传统的功能分类,在动物中,组织蛋白酶L．1ike家族成员包括组织蛋白酶L、V、S、K、H和F。但是这些家族成员之间的进化关系仍然没有详细研究分析清楚。本课题主要研究组织蛋白酶L-like家族成员之间的进化关系。方法：本研究通过搜集整理22个物种的177条组织蛋白酶L-1ike家族蛋白的序列,并构建系统发育进化树来分析组织蛋白酶L-like家族各成员之间的进化关系。结果：序列数据结果显示,串联重复在组织蛋白酶L-1ike家族的进化过程中发生。斑马鱼的组织蛋白酶L,爪蟾的组织蛋白酶S和K,大鼠和小鼠的组织蛋白酶L都发生过明显的串联重复事件。进化树结果显示了组织蛋白酶H、S和K、L和V之间的进化关系,组织蛋白酶S和K在脊椎动物出现的进化过程中,从组织蛋白酶L中分化出来,与他们在脊椎动物体内的特异性功能,以及脊椎动物在进化过程中分化产生的特异性功能相对应。结论：在物种进化的过程中,组织蛋白酶L-1ike家族成员F、H、S和K、L和V按时间顺序分化,这表明组织蛋白酶L-1ike基因家族结构和功能的分化与新的物种和新的功能出现密切相关。