Distribution and phylogenetic significance of the 71-kb inversion in the plastid genome in Funariidae (Bryophyta)

BACKGROUND AND AIMS: The recent assembly of the complete sequence of the plastid genome of the model taxon Physcomitrella patens (Funariaceae, Bryophyta) revealed that a 71-kb fragment, encompassing much of the large single copy region, is inverted. This inversion of 57% of the genome is the largest rearrangement detected in the plastid genomes of plants to date. Although initially considered diagnostic of Physcomitrella patens, the inversion was recently shown to characterize the plastid genome of two species from related genera within Funariaceae, but was lacking in another member of Funariidae. The phylogenetic significance of the inversion has remained ambiguous. METHODS: Exemplars of all families included in Funariidae were surveyed. DNA sequences spanning the inversion break ends were amplified, using primers that anneal to genes on either side of the putative end points of the inversion. Primer combinations were designed to yield a product for either the inverted or the non-inverted architecture. KEY RESULTS: The survey reveals that exemplars of eight genera of Funariaceae, the sole species of Disceliaceae and three generic representatives of Encalyptales all share the 71-kb inversion in the large single copy of the plastid genome. By contrast, the plastid genome of Gigaspermaceae (Funariales) is characterized by a gene order congruent with that described for other mosses, liverworts and hornworts, and hence it does not possess this inversion. CONCLUSIONS: The phylogenetic distribution of the inversion in the gene order supports a hypothesis only weakly supported by inferences from sequence data whereby Funariales are paraphyletic, with Funariaceae and Disceliaceae sharing a common ancestor with Encalyptales, and Gigaspermaceae sister to this combined clade. To reflect these relationships, Gigaspermaceae are excluded from Funariales and accommodated in their own order, Gigaspermales order nov., within Funariideae.     

木薯ftsZ基因分离及在原核生物中功能初步鉴定

ftsZ基因是控制细胞分裂的关键基因,其蛋白能够在分裂位点形成一个环状结构而影响细胞分裂.为了研究木薯质体分裂与木薯淀粉品质形成的关系,根据木薯基因组数据库上的预测序列,设计引物,从木薯基因组中分离了与质体分裂相关的ftsZ家族3个新基因(ftsZ1,ftsZ2,ftsZ3).分别将它们与荧光蛋白基因(GFP)融合,构建了3个原核表达载体pET-fisZ1-GFP、pET-fisZ2-GFP、pET-fisZ3-GFP,并转化大肠杆菌BL21(DE3).通过荧光显微镜观察菌体的表型和分裂,初步鉴定了木薯质体分裂相关基因ftsZ家族对细胞分裂的作用.结果显示:尽管木薯与大肠杆菌的亲缘关系较远,ftsZ基因的同源性较低,但是两者表现出相似的功能,木薯ftsZ基因的表达能严重影响大肠杆菌细胞分裂.这一结果为进一步研究木薯ftsZ家族基因的功能奠定了基础.     

Isolation of mutant lines with decreased numbers of chloroplasts per cell from a tagged mutant library of the moss Physcomitrella patens

Eleven mutant lines exhibiting decreased numbers of chloroplasts per cell were isolated from 8 800 tagged mutant lines of Physcomitrella patens by microscopic observations. Chloronema subapical cells in wild-type plants had a mean of 48 chloroplasts, whereas chloroplast numbers in subapical cells in mutant lines 215 and 222 decreased to 75 % of that in the wild type. Seven mutant lines - 473, 122, 221, 129, 492, 207, and 138 - had about half as many chloroplasts as the wild type. Mutant line 11 had a few remarkably enlarged chloroplasts, and mutant line 347 had chloroplasts of various sizes. Whereas the cell volume was the same as in the wild type in mutant lines 222, 473, 221, 129, 492, and 207, the cell volume of the other mutants increased. The chloroplast number of leaf cells was the same as that of chloronema cells in each mutant line when gametophores could be formed. Treatment with ampicillin decreased the number of chloroplasts in all mutant lines. Southern hybridization using DNA in tags as probes showed that only one insertion occurred in mutant lines 473 and 221. To determine whether the tagged DNA inserted into the known genes for plastid division, we isolated the PpMinD1, PpMinD2, and PpMinE1 genes. Genomic polymerase chain reaction analysis showed that the PpFtsZ and PpMinD/E genes were not disrupted by the insertion of the tags in mutant lines 11 and 347, respectively.     

Early evolution of the MFT-like gene family in plants

Angiosperm genes sharing a conserved phosphatidylethanolamine-binding (PEPB) domain have been shown to be involved in the control of shoot meristem identity and flowering time. The family is divided into three subfamilies, FT-like, TFL1-like and MFT-like. This study is focused on the evolution of the MFT-like clade, suggested to be ancestral to the two other clades. We report that the bryophyte Physcomitrella patens and the lycopod Selaginella moellendorfii contain four and two MFT-like genes respectively. Neither species have any FT or TFL1-like genes. Furthermore, we have identified a new subclade of MFT-like genes in Angiosperms. Quantitative expression analysis of MFT-like genes in Physcomitrella patens reveals that the expression patterns are circadian and reaches maximum in gametangia and sporophytes. Our data suggest that the occurrence FT and TFL1-like genes, is associated with the evolution of seed plants. Expression data for Physcomitrella MFT-like genes implicates an involvement in the development of reproductive tissues in the moss.     

The Role of Morphological Biochemical Reciprocity in Early Land Plant Evolution

A morphological-biochemical reciprocity is used to constructa scenario for the evolution of the land and vascular planthabits. The optimal designs of autotrophs are shown to be limitedby their biosynthetic capacities, i.e., the morphological mannerin which surface area-dependent functions are maintained withincreasing size is primarily dictated by the availability ofspecific architectural polymers. The evolution of biosyntheticpathways (involving the detoxification-conversion of primarymetabolites into useful architectural polymers, e.g., cellulose,lignin) predates and allows for transitions from simple dichotomous-convolutedmorphologies to ‘tree-like’ erect plants. The reciprocitybetween morphology and biochemistry is seen to result in a stratifiedstability, i.e., optimal designs, parameterized by their biosyntheticcapacities, result in a hierarchy of stable forms, which undergotransitions when environmental factors alter. Finite element analyses of geometric forms, showing a size increasewith constant surface area-to-volume ratios, indicate simplelobed or convoluted structures are optimal designs for primitivenon-vascular plants, while physical parameters defining theoptimal design of erect plants indicate the necessity for differentialtissue density. Selective pressures favouring an erect plantposture (photosynthetic rates; reproduction) coupled with achemosynthetic ability to structurally reinforce specializedconductive cells is seen to result in the lignification of tracheid-likecells.     

Evolution of ABCA4 Proteins in Vertebrates

The ABCA4 (ABCR) gene encodes a retinal-specific ATP-binding cassette transporter. Mutations in ABCA4 are responsible for several recessive macular dystrophies and susceptibility to age related macular degeneration (AMD). The protein appears to function as a flippase of all-trans-retinaldehyde and/or its derivatives across the membrane of outer segment disks and is a potentially important element in recycling visual cycle metabolites. However, the understanding of ABCA4s role in the visual cycle is limited due to the lack of a direct functional assay. An evolutionary analysis of ABCA4 may aid in the identification of conserved elements, the preservation of which implies functional importance. To date, only human, murine, and bovine ABCA4 genes are described. We have identified ABCA4 genes from African (Xenopus laevis) and Western (Silurana tropicalis) clawed frogs. A comparative analysis describing the evolutionary relationships between the frog ABCA4s, annotated T. rubripes ABCA4, and mammalian ABCA4 proteins was carried out. Several segments are conserved in both intradiscal loop (IL) domains, in addition to the transmembrane and ATP-binding domains. Nonconserved segments were found in the IL and cytoplasmic linker domains. Maximum likelihood analyses of the aligned sequences strongly suggest that ABCA4 was subject to purifying selection. Collectively, these data corroborate the current evolutionary model where two distinct ABCA half-transporter progenitors were combined to form a full ABCA4 progenitor in ancestral chordates. We speculate that evolutionary alterations may increase the retinoid metabolite recycling capacity of ABCA4 and may improve dark adaptation.Reviewing Editor: Dr. Peer Bork     

Diversification Pattern of the HMG and SOX Family Members During Evolution

From a database containing the published HMG protein sequences, we constructed an alignment of the HMG box functional domain based on sequence identity. Due to the large number of sequences (more than 250) and the short size of this domain, several data sets were used. This analysis reveals that the HMG box superfamily can be separated into two clearly defined subfamilies: (i) the SOX/MATA/TCF family, which clusters proteins able to bind to specific DNA sequences; and (ii) the HMG/UBF family, which clusters members which bind non specifically to DNA. The appearance and diversification of these subfamilies largely predate the split between the yeast and the metazoan lineages. Particular emphasis was placed on the analysis of the SOX subfamily. For the first time our analysis clearly identified the SOX subfamily as structured in six groups of genes named SOX5/6, SRY, SOX2/3, SOX14, SOX4/22, and SOX9/18. The validity of these gene clusters is confirmed by their functional characteristics and their sequences outside the HMG box. In sharp contrast, there are only a few robust branching patterns inside the UBF/HMG family, probably because of the much more ancient diversification of this family than the diversification of the SOX family. The only consistent groups that can be detected by our analysis are HMG box 1, vertebrate HMG box 2, insect SSRP, and plant HMG. The various UBF boxes cannot be clustered together and their diversification appears to be extremely ancient, probably before the appearance of metazoans. Received: 20 July 1998 / Accepted: 19 October 1998     

Plasticity of Fitness and Diversification Process During an Experimental Molecular Evolution

A simplified experimental evolution encompassing the essence of natural one was designed in an attempt to understand the involved mechanism. In our system, molecular evolution was observed through three serial cycles of consecutive random mutagenesis of the glutamine synthetase gene and chemostat culture of the transformed Escherichia coli cells containing the mutated genes. Selection pressure was imposed solely on the glutamine synthetase gene when varieties of mutant genes compete in an unstructured environment of the chemostat. The molecular phylogeny and population dynamics were deduced from the nucleotide sequences of the genes isolated from each of the chemostat runs. An initial mutant population in each cycle, comprised of diversified closely-related genes, ended up with several varieties of mutants in a state of coexistence. Competition between two mutant genes in the final population of the first cycle ascertained that the observed coexisting state is not an incidental event and that cellular interaction via environmental nutrients is a possible mechanism of coexistence. In addition, the mutant gene once extinct in the previous passage was found to have the capacity to reinvade and constitute the gene pool of the later cycle of molecular evolution. These results, including the kinetic characteristics of the purified wild-type and mutant glutamine synthetases in the phylogenetic tree, revealed that the enzyme activity had diverged, rather than optimized, to a fittest value during the course of evolution. Here, we proposed that the plasticity of gene fitness in consequence of cellular interaction via the environment is an essential mechanism governing molecular evolution. Received: 29 August 2000 / Accepted: 25 January 2001     

Filamentous temperature-sensitive Z (FtsZ) isoforms specifically interact in the chloroplasts and in the cytosol of Physcomitrella patens

Plant filamentous temperature-sensitive Z (FtsZ) proteins have been reported to be involved in biological processes related to plastids. However, the precise functions of distinct isoforms are still elusive. Here, the intracellular localization of the FtsZ1-1 isoform in a moss, Physcomitrella patens, was examined. Furthermore, the in vivo interaction behaviour of four distinct FtsZ isoforms was investigated. Localization studies of green fluorescent protein (GFP)-tagged FtsZ1-1 and fluorescence resonance energy transfer (FRET) analyses employing all dual combinations of four FtsZ isoforms were performed in transient protoplast transformation assays. FtsZ1-1 is localized to network structures inside the chloroplasts and exerts influence on plastid division. Interactions between FtsZ isoforms occur in distinct ordered structures in the chloroplasts as well as in the cytosol. The results expand the view of the involvement of Physcomitrella FtsZ proteins in chloroplast and cell division. It is concluded that duplication and diversification of ftsZ genes during plant evolution were the main prerequisites for the successful remodelling and integration of the prokaryotic FtsZ-dependent division mechanism into the cellular machineries of distinct complex processes in plants.     

HPV基因的进化分析

目的:HPV有许多类型,其大致可分为高危型和低危型,高危型HPV感染是导致宫颈癌发生的首要原因,在HPV基因组中,E6基因是促进宫颈细胞癌变的关键基因,本文主要研究HPV中的E6基因在各种不同型别的HPV中的进化关系,并对E2基因碱基替换率进行分析,探讨高危型HPV与低危型HPV的区别.方法:本文对不同类型HPV E6氨基酸序列构建系统发生树,探讨识别高危型HPV可能的一致序列,对E6基因其中一处能导致恶性程度增加的突变进行分析.并对HPV16与其位于同一颗树的HPV35和HPV31计算相对碱基替换率.结果:高危型HPV均源自同一株病毒株的进化.各种HPV型别中,高危型HPV E6蛋白对应于HPV16E6蛋白的第83位氨基酸为缬氨酸更为保守,HPV中除E2以外的其他基因的非同义替换率均小于同义替换率.结论:HPV E6蛋白对应于HPV16E6蛋白的第83位氨基酸为缬氨酸能更好地实现HPV E6蛋白的致癌作用.HPV基因中除E2以外的基因在进化过程中都较为保守,是HPV增殖生长的关键基因,而E2部分区域非同义替换率大于同义替换率,说明E2这部分区域的突变能够更好的促进HPV的增殖和生长.     

Observations on dividing plastids in the protonema of the moss Funaria hygrometrica Sibth.

The process of division was investigated in the different types of plastids found in the tip cell of the protonema of Funaria hygrometrica Sibth. There were no structural changes in the envelope membranes of any of the plastid types during the initial stage of division. As the process of constriction advanced, thylakoids were locally disintegrated and sometimes starch grains in the isthmus were locally dissolved. In the isthmus, tightly constricted plastids were characterized by an undulating envelope and an increasing number of vesicles. After three-dimensional reconstruction of electronmicrographs a distinct filamentous structure was observed in the plane of division outside the plastid but close to the envelope. At different stages of division the constricted regions were partly surrounded by one or a few filaments. The roundish plastids in the apical zone were accompanied by single microtubule bundles, and the spindle-shaped plastids in the cell base were surrounded by single microtubules and microtubule bundles. A model of co-operation between microtubules and the filamentous structure in the division process is discussed.A preliminary report was presented at the Tagung der Deutschen Botanischen Gesellschaft und der Vereinigung für Angewandte Botanik, Hamburg, September 1986     

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。     

Evolution of the proteinase inhibitor I family and apparent lack of hypervariability in the proteinase contact loop

A protein phylogenetic tree was constructed from 24 homologous proteinase inhibitor I sequences identified in the EMBUGenbank and Swiss-Prot databases and from translated amino acid data from four constitutive cDNA clones of proteinase inhibitor I characterized from potato tuber mRNA. The tree suggests that divergence of at least four paralogous proteins with functional specialization occurred at different times during the evolutionary history of the proteinase inhibitor I family. Five distinct regions in the primary structure, earlier identified by structural studies, were used to analyze the inhibitor family for hypervariability (Creighton and Darby, Trends Biochem Sci 14:319–324, 1989). Mutations did not occur with higher-than-random frequency within the proteinase binding region. When isoinhibitor, orthologous, or paralogous data subsets were subsequently analyzed the same results were obtained. Comparison of the amino acid sequences for all the known potato proteinase isoinhibitor I proteins identified ten highly variable sites. These also were distributed randomly. Thus hypervariability, which has been observed in all other serine proteinase inhibitor families to date, appears to be lacking in the proteinase inhibitor I family.     

Evolution of RNA polymerases and branching patterns of the three major groups of archaebacteria

Summary The amino acid sequences of the largest subunits of the RNA polymerases I, II, and III from eukaryotes were compared with those of archaebacterial and eubacterial homologs, and their evolutionary relationships were analyzed in detail by a recently developed tree-making method, the likelihood method of protein phylogeny, as well as by the neighbor-joining method and the parsimony method, together with bootstrap analyses. It was shown that the best tree topologies predicted by the first two methods are identical, whereas the last one predicts a distinct tree. The maximum likelihood tree revealed that, after the separation from archaebacteria, the three eukaryotic RNA polymerases diverged from an ancestral precursor in the eukaryotic lineage. This result is contrasted with the published result showing multiple origins for the three eukaryotic polymerases. It was shown that eukaryotic RNA polymerase I evolved much more rapidly than RNA polymerases II and III: The N-terminal half of RNA polymerase I shows an extraordinarily high evolutionary rate, possibly due to relaxed functional constraints. In contrast the evolutionary rate of archaebacterial RNA polymerase is remarkably limited. In addition, including the second largest subunit of the RNA polymerase, a detailed analysis for the branching pattern of the three major groups of archaebacteria was carried out by the maximum likelihood method. It was shown that the three major groups of archaebacteria are likely to form a single cluster; that is, archaebacteria are likely to be monophyletic as originally proposed by Woese and his colleagues.     

促葡萄糖转运蛋白基因家族的分子进化研究

葡萄糖转运蛋白是一个在结构上相似功能上不同的多基因家族（ＧＬＵＴ１－ＧＬＵＴ５）。由于这一组蛋白和体内的葡萄糖利用有关,因此被认为是糖尿病胰岛素抵抗（抗性）的一个候选基因。本文比较了不同种生物这一基因家族的氨基酸和核苷酸顺序;推测了亲水性和疏水性分布;计算了蛋白质和核苷酸的进化距离,并在此基础上构建了分子进化树。研究表明：这一基因家族具有高度的同源性、极为相似的亲水性和疏水性分布以及结构的对称性。提示这一基因家族起源于一个共同的祖先并可能通过基因的重复而形成。这一进化机制可能有利于氨基酸结构的稳定及抵抗突变的作用。由于邻元法构建的进化树其分支长度存在差异,提示在这一基因家族的进化过程中,各分支上的进化速率并不相同。蛋白质进化距离和核苷酸进化距离所构建进化树的差异提示了在基因组中可能存在隐匿替换。两种方法构建的进化树都提示了ＧＬＵＴ１、３、４在结构和功能上要更为保守。     

过氧化氢酶基因定向进化文库的构建及其评价

采用易错聚合酶链反应和DNA改组技术构建野生型梅花鹿过氧化氢酶(CAT)基因的突变体文库,并随机对两种方法所得产物各5个样品做序列测定。序列分析结果表明突变率分别为0.329%和27.58%,易错聚合酶链反应体系的错配率可以比普通PCR体系提高约10倍,DNA改组的突变率则更高,但是难以避免由于突变率太高造成的目的基因无法正确翻译这一情况。另外,应用邻接法(neighbor-joining, NJ)对随机选择的过氧化氢酶基因突变体序列和野生型序列做核酸和蛋白质序列的NJ进化树,进化关系与突变率分析基本一致。