共查询到16条相似文献,搜索用时 93 毫秒
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扩展蛋白(Expansins,EXP)是一类基因家族,几乎参与了植物发育的全过程,从种子萌发到果实成熟都有扩展蛋白的参与。该研究利用生物信息学的方法对小立碗藓(Physcomitrella patens) Expansin基因家族成员进行鉴定,分析了其基因结构、染色体定位以及系统发生关系。结果表明:小立碗藓基因组中含有Expansin A(EXPA) 32个、Expansin-like A(EXLA) 6个,并未发现Expansin-like B(EXLB)及Expansin B(EXPB)。扩展蛋白氨基酸序列长度在228~290 aa之间,编码蛋白质具有两个保守的结构域Pollen_allerg_1和DPBB_1。蛋白质亚细胞定位预测结果表明:运用CELLO在线工具预测发现小立碗藓中约4/5的EXP家族基因定位于细胞外;而Euk-mPLoc预测结果则显示小立碗藓EXP基因家族成员全定位于细胞外。基因结构分析表明,小立碗藓中约68%Expansin基因有含有1~3个内含子。以上结果可为深入研究小立碗藓扩展蛋白基因的分子进化与生物学功能奠定基础。 相似文献
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苔藓植物小立碗藓是迄今发现的同源重组率最高的陆生植物,堪与酵母媲美,具有"绿色酵母"之称。高的同源重组频率、简单的发育模式以及单倍体配子体为主的生活史使其渐渐成为研究生物学进程和发育模式的新型模式生物。现对近年来小立碗藓遗传转化系统研究的进展进行总结和分析,为相关研究工作者充分利用这一体系提供帮助。对小立碗藓遗传表达系统的载体构建、转化方法及宿主细胞准备等方面的进展进行了综述,对小立碗藓在基因打靶方面的应用进行了简要总结。 相似文献
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利用857条植物miRNA序列对27546条小立碗藓mRNA序列进行搜索,预测出162个植物miRNA家族在小立碗藓中存在结合靶位。miRNA结合靶位数目和miRNA协同作用网络分析结果同时显示,miR482和miR1168在小立碗藓中结合靶位多、协同作用广,提示它们对于小立碗藓可能具有重要生物学功能。52个菜茵衣藻特有的miRNA被预测在小立碗藓中存在结合靶位,显示小立碗藓在从藻类向种子植物进化过程中处在独特演化位置。 相似文献
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根据基因组信息和KEGG数据库分析小立碗藓基因组中合成萜类物质的基因,比较小立碗藓与酵母和拟南芥合成萜类物质基因的氨基酸序列同源性同时利用UPLC-QTOF分析小立碗藓中物质组成,来分析小立碗藓基因组中萜类物质合成的基因及小立碗藓中存在的萜类物质。与酵母相比,小立碗藓两条萜类次生代谢途径完整,途径中的基因及氨基酸丰富性更高,提示可以合成更丰富的前体物质如FPP,GPP等;小立碗藓与拟南芥的序列相似性较高,萜类背景简单。UPLC-QTOF分析检测到小立碗藓中次生代谢物质主要是芳香族化合物及各类生物碱,一种萜类物质ent-16beta-Methoxy-19-kauranoic acid。小立碗藓中本身具有合成萜类前体物质和二萜的基因,检测到少量萜类物质,适合作为萜类活性物质异源合成的底盘细胞。 相似文献
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小立碗藓MADS-box基因家族的系统进化分析 总被引:2,自引:0,他引:2
苔藓植物作为最早出现的陆生植物的代表,生活周期仍以配子体为主,在植物进化史上占据着重要的地位。另外,同源异型基因MADS-box家族广泛参与植物的生长发育和形态构建。因此,对苔藓植物MADS-box家族的分析有助于了解苔藓植物出现过程中发生的重要分子事件和关键器官革新。我们基于最新公布的小立碗藓基因组数据库确定了20个带有典型MADS结构域的MADS-box基因,其中11个MIKC~*型、5个MIKC~C型、4个I型,并对它们进行了染色体定位、外显子-内含子基因结构、蛋白结构域组成、系统进化构建等分析,为进一步阐明小立碗藓MADS-box基因的功能提供了准确的信息资源。 相似文献
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小立碗藓作为植物分子生物学研究极具前景的模式系统已日益受到人们的重视,它的生活史周期短,易于培养,转基因植株易于分析,核基因组容易和外源DNA 发生同源重组,这些特点使它成为研究基因功能的良好材料。一些成功的基因敲除和基因破坏已经在小立碗藓中实现,这些基因的功能也通过小立碗藓转化植株的特点得以证实。小立碗藓标签突变文库已经建立,其应用为小立碗藓基因的进一步研究打下了基础。关于小立碗藓的ESTs 数据库已经建立,已有67 000 条ESTs 信息。 相似文献
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Schween G Egener T Fritzowsky D Granado J Guitton MC Hartmann N Hohe A Holtorf H Lang D Lucht JM Reinhard C Rensing SA Schlink K Schulte J Reski R 《Plant biology (Stuttgart, Germany)》2005,7(3):228-237
Gene targeting in the moss Physcomitrella patens has created a new platform for plant functional genomics. We produced a mutant collection of 73 329 Physcomitrella plants and evaluated the phenotype of each transformant in comparison to wild type Physcomitrella. Production parameters and morphological changes in 16 categories, such as plant structure, colour, coverage with gametophores, cell shape, etc., were listed and all data were compiled in a database (mossDB). Our mutant collection consists of at least 1804 auxotrophic mutants which showed growth defects on minimal Knop medium but were rescued on supplemented medium. 8129 haploid and 11 068 polyploid transformants had morphological alterations. 9 % of the haploid transformants had deviations in the leaf shape, 7 % developed less gametophores or had a different leaf cell shape. Other morphological deviations in plant structure, colour, and uniformity of leaves on a moss colony were less frequently observed. Preculture conditions of the plant material and the cDNA library (representing genes from either protonema, gametophore or sporophyte tissue) used to transform Physcomitrella had an effect on the number of transformants per transformation. We found correlations between ploidy level and plant morphology and growth rate on Knop medium. In haploid transformants correlations between the percentage of plants with specific phenotypes and the cDNA library used for transformation were detected. The number of different cDNAs present during transformation had no effect on the number of transformants per transformation, but it had an effect on the overall percentage of plants with phenotypic deviations. We conclude that by linking incoming molecular, proteome, and metabolome data of the transformants in the future, the database mossDB will be a valuable biological resource for systems biology. 相似文献
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Gene targeting in Physcomitrella patens 总被引:8,自引:0,他引:8
Schaefer DG 《Current opinion in plant biology》2001,4(2):143-150
Gene-targeting efficiency in the land plant Physcomitrella patens (Bryophyta) can only be compared with that observed in Saccharomyces cerevisiae. Sequencing programs and microbiological molecular genetic approaches are now being developed to unravel the precise function of plant genes. Physcomitrella patens, as the new 'green yeast', might well become a major tool for functional genomic studies of multicellular eukaryotes. 相似文献
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von Schwartzenberg K 《Plant biology (Stuttgart, Germany)》2006,8(3):382-388
Mosses present several advantages for the analysis of phytohormone physiology. Their enormous regeneration capacity, the possibility of controlling their whole life cycle under in vitro culture conditions, as well as the small number of cell types facilitate studies of hormone homeostasis. This review focuses on the metabolism and biosynthesis of cytokinins, mostly summarising data obtained using the moss Physcomitrella patens (Hedw.) B.S.G. which has served as a model system for cytokinin research for many years. A comparison of metabolic differences with respect to seed plants is presented, pointing out an important role of adenosine kinase for the formation of nucleotides during cytokinin interconversion in Physcomitrella. Results on cytokinin biosynthesis in Physcomitrella are summarised with respect to the OVE mutants, which can be considered unique in the plant kingdom due to their strong overproduction of cytokinins. The OVE phenotype is correlated with both increased activity in early stages of cytokinin biosynthesis as well as increased conversion of cytokinin riboside to the base. Cytokinin interconverting reactions can contribute to the increased levels of cytokinins in OVE mutants. Further studies on hormone physiology in moss will help to complete our understanding of hormonal homeostasis by elucidating the situation in an evolutionary early embryophyte. 相似文献
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Recently, the moss Physcomitrella patens was established as a versatile tool in plant functional genomics. Mosses represent the oldest living clade of land plants, separated by approximately 450 million years of evolution from crop plants. Consequently, mosses contain metabolites and genes not known from these seed plants. In Physcomitrella, nuclear genes can be targeted by homologous recombination as efficiently as in yeast, allowing reverse genetics approaches in plants at high-throughput levels for the first time. Comprehensive expressed sequence tag databases gave new insights into the levels of diversity in land plants which are now ready to be exploited in plant biotechnology. In forward genetics screens, saturated tagged mutant collections help to unravel novel gene - function relationships. Additionally, proteomics tools are at hand to analyse subcellular proteomes, as well as the phosphoproteome, as the core of eukaryotic signal transduction. Moreover, specifically designed Physcomitrella strains can produce human therapeutic proteins safely and cost-effectively in bioreactors. 相似文献
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Mapping of the Physcomitrella patens proteome 总被引:2,自引:0,他引:2
The moss Physcomitrella patens is unique among land plants due to the high rate of homologous recombination in its nuclear DNA. The feasibility of gene targeting makes Physcomitrella an unrivalled model organism in the field of plant functional genomics. To further extend the potentialities of this seed-less plant we aimed at exploring the P. patens proteome. Experimental conditions had to be adopted to meet the special requirements connected to the investigations of this moss. Here we describe the identification of 306 proteins from the protonema of Physcomitrella. Proteins were separated by two dimensional electrophoresis, excised form the gel and analysed by means of mass spectrometry. This reference map will lay the basis for further profound studies in the field of Physcomitrella proteomics. 相似文献