蕨类植物MADS盒基因研究概况

MADS盒基因是生物重要的调控基因家族.简述了MADS盒基因的分类、分布和功能及种子植物MADS盒基因研究及一种苔藓植物的MADS盒基因概况,对目前从蕨类植物中分离定性的MADS盒基因与种子植物相比具有的特点及其演化关系进行了重点介绍.     

Regulatory mechanism controlling stomatal behavior conserved across 400 million years of land plant evolution

Stomatal pores evolved more than 410 million years ago [1,?2]?and allowed vascular plants to regulate transpirational water loss during the uptake of CO(2) for photosynthesis [3]. Here, we show that stomata on the sporophytes of the moss Physcomitrella patens [2] respond to environmental signals in a similar way to those of flowering plants [4] and that a homolog of a key signaling component in the vascular plant drought hormone abscisic acid (ABA) response [5] is?involved in stomatal control in mosses. Cross-species complementation experiments reveal that the stomatal ABA response of a flowering plant (Arabidopsis thaliana) mutant, lacking the ABA-regulatory protein kinase OPEN STOMATA 1 (OST1) [6], is rescued by substitution with the moss P.?patens homolog, PpOST1-1, which evolved more than 400 million years earlier. We further demonstrate through the targeted knockout of the PpOST1-1 gene in P.?patens that its role in guard cell closure is conserved, with stomata of mutant mosses exhibiting a significantly attenuated ABA response. Our analyses indicate that core regulatory components involved in guard cell ABA signaling of flowering plants are operational in mosses and likely originated in the last common ancestor of these lineages more than 400 million years ago [7], prior to the evolution of ferns [8, 9].     

Characterization of a PDK1 homologue from the moss Physcomitrella patens

The serine/threonine protein kinase 3-phosphoinositide-dependent protein kinase 1 (PDK1) is a highly conserved eukaryotic kinase that is a central regulator of many AGC kinase subfamily members. Through its regulation of AGC kinases, PDK1 controls many basic cellular processes, from translation to cell survival. While many of these PDK1-regulated processes are conserved across kingdoms, it is not well understood how PDK1 may have evolved within kingdoms. In order to better understand PDK1 evolution within plants, we have isolated and characterized the PDK1 gene from the moss Physcomitrella patens (PpPDK1), a nonvascular representative of early land plants. PpPDK1 is similar to other plant PDK1s in that it can functionally complement a yeast PDK1 knockout line. However, unlike PDK1 from other plants, the P. patens PDK1 protein does not bind phospholipids due to a lack of the lipid-binding pleckstrin homology domain, which is used for lipid-mediated regulation of PDK1 activity. Sequence analysis of several PDK1 proteins suggests that lipid regulation of PDK1 may not commonly occur in algae and nonvascular land plants. PpPDK1 can phosphorylate AGC kinase substrates from tomato (Solanum lycopersicum) and P. patens at the predicted PDK1 phosphorylation site, indicating that the PpPDK1 substrate phosphorylation site is conserved with higher plants. We have also identified residues within the PpPDK1 kinase domain that affect kinase activity and show that a mutant with highly reduced kinase activity can still confer cell viability in both yeast and P. patens. These studies lay the foundation for further analysis of the evolution of PDK1 within plants.     

A novel gene family in moss (Physcomitrella patens) shows sequence homology and a phylogenetic relationship with the TIR-NBS class of plant disease resistance genes

Plant disease resistance (R) genes encode proteins in which several motifs of the nucleotide-binding region (NBS) are highly conserved. Using degenerate primers designed according to the kinase 1 (P-loop) and hydrophobic (HD) motifs of the R gene NBS domains, homologous sequences were cloned from moss (Physcomitrella patens; phylum Bryophyta) representing an ancient nonvascular plant. A novel gene family (PpC) with at least eight homologous members was found. Expression of five members was detected. The level of expression was dependent on the developmental stage of moss, being higher in the gametophyte tissue than in the protonema tissue. The PpCs contained the conserved motifs characteristic of the NBS regions of R genes, and a kinase domain was found upstream from the NBS region. Phylogenetic analysis using the deduced NBS amino acid sequences of the PpCs and the plant genes available in databanks indicated that the PpCs show the closest relationship with the TIR-NBS class of R genes. No significant similarity to plant genes other than R genes was observed. These findings shed novel light on the evolutionary history of the R gene families, suggesting that the NBS region characteristic of the TIR-NBS class of R-like genes evolved prior to the evolutionary differentiation of vascular and nonvascular plants.     

Cloning and characterization of chalcone synthase from the moss, Physcomitrella patens

Since the early evolution of land plants from primitive green algae, flavonoids have played an important role as UV protective pigments in plants. Flavonoids occur in liverworts and mosses, and the first committed step in the flavonoid biosynthesis is catalyzed by chalcone synthase (CHS). Although higher plant CHSs have been extensively studied, little information is available on the enzymes from bryophytes. Here we report the cloning and characterization of CHS from the moss, Physcomitrella patens. Taking advantage of the available P. patens EST sequences, a CHS (PpCHS) was cloned from the gametophores of P. patens, and heterologously expressed in Escherichia coli. PpCHS exhibited similar kinetic properties and substrate preference profile to those of higher plant CHS. p-Coumaroyl-CoA was the most preferred substrate, suggesting that PpCHS is a naringenin chalcone producing CHS. Consistent with the evolutionary position of the moss, phylogenetic analysis placed PpCHS at the base of the plant CHS clade, next to the microorganism CHS-like gene products. Therefore, PpCHS likely represents a modern day version of one of the oldest CHSs that appeared on earth. Further, sequence analysis of the P. patens EST and genome databases revealed the presence of a CHS multigene family in the moss as well as the 3'-end heterogeneity of a CHS gene. Of the 19 putative CHS genes, 10 genes are expressed and have corresponding ESTs in the databases. A possibility of the functional divergence of the multiple CHS genes in the moss is discussed.     

小立碗藓WRKY基因家族生物信息学分析

WRKY作为最先在植物中发现的转录因子,在植物生长发育等过程中发挥重要作用。为了更好地研究小立碗藓WRKY蛋白的结构与功能,该文以Pfam数据库中WRKY基因家族数据(登录号为PF03106)为材料,分析了小立碗藓(Physcomitrella patens)WRKY基因家族成员的理化性质、蛋白质的二级结构预测、染色体定位、内外显子分布及系统进化关系。结果表明:(1)小立碗藓WRKY基因家族成员共有38个基因,根据WRKY保守结构域个数和锌指结构类型分成Ⅰ、Ⅱ两大类,不含第Ⅲ类(锌指结构为C2HC型),其中部分基因WRKY保守结构域发生变异。(2)WRKY蛋白氨基酸长度在216~775 aa之间、相对分子质量在24.5~82.8 kDa之间,亚细胞定位显示WRKY家族成员蛋白质定位于细胞核中。(3)WRKY蛋白的二级结构以α-螺旋、延伸链、β-转角、无规卷曲四种构成元件构成,除PpWRKY11(α-螺旋为主)外,其余无规卷曲占比高达70%。(4)与拟南芥的系统进化关系表明,植物在进化过程中WRKY家族成员的数目与进化方式发生改变,WRKY基因家族成员外显子的个数为3~7个。(5)小立碗藓WRKY基因家族成员无规则分散于21条染色体上,并未形成基因簇。该研究通过分析WRKY基因家族的基本结构与性质,能为后续深入研究WRKY转录因子的功能奠定基础。     

Exploring plant biodiversity: the Physcomitrella genome and beyond

For decades, plant molecular biology has focused on only a few angiosperm species. Recently, the approximately 500mega base pairs (Mb) of the haploid Physcomitrella patens genome were sequenced and annotated. Mosses such as P. patens occupy a key evolutionary position halfway between green algae and flowering plants. This draft genome, in comparison to existing genome data from other plants, allows evolutionary insights into the conquest of land by plants and the molecular biodiversity that land plants exhibit. As a model organism, P. patens provides a well-developed molecular toolbox, including efficient gene targeting in combination with the morphologically simple moss tissues. We describe current as well as future tools for P. patens research and the prospects they offer for plant research in general.