Ancestry of plant MADS-box genes revealed by bryophyte (Physcomitrella patens) homologues

Three MADS-box cDNA clones and two corresponding genomic sequences (gDNAs) have been isolated from the bryophyte Physcomitrella patens and sequenced. Our findings indicate that the genes may be expressed in a tissue- or age-specific manner, and that expression of one of them is regulated by an alternative splicing mechanism. Conceptual translation of the clones reveals that the encoded MADS-domain proteins have the typical plant-domain pattern (MIKC). Additionally, there is a high degree of conservation of intron number and positions between angiosperm MADS-box genes and the moss loci. These observations confirm the homology of moss and higher plant MADS-box genes. We conclude that the MIKC pattern evolved in MADS-box genes after the separation of the plant lineage from that of fungi and animals, and that it must have been present in the common ancestor of mosses, ferns and seed plants. Therefore it evolved at least 400 million yr ago. Phylogenetic analysis of a large subset of the sequenced plant MADS-box genes, incorporating those from P. patens , indicates that the bryophyte genes are not orthologues of spermatophyte genes belonging to any of the well recognized higher plant gene subfamilies. This conclusion accords well with reports that the known fern MADS-box genes also comprise subfamilies distinct from those of higher plants. Therefore we tentatively propose that the gene duplication and diversification events that created the MADS-box gene subfamilies, discernible in extant angiosperm and other spermatophyte groups, occurred after separation of the moss and fern lineages from the lineage which produced the higher plants.     

Antiquity and evolution of the MADS-box gene family controlling flower development in plants

MADS-box genes in plants control various aspects of development and reproductive processes including flower formation. To obtain some insight into the roles of these genes in morphological evolution, we investigated the origin and diversification of floral MADS-box genes by conducting molecular evolutionary genetics analyses. Our results suggest that the most recent common ancestor of today's floral MADS-box genes evolved roughly 650 MYA, much earlier than the Cambrian explosion. They also suggest that the functional classes T (SVP), B (and Bs), C, F (AGL20 or TM3), A, and G (AGL6) of floral MADS-box genes diverged sequentially in this order from the class E gene lineage. The divergence between the class G and E genes apparently occurred around the time of the angiosperm/gymnosperm split. Furthermore, the ancestors of three classes of genes (class T genes, class B/Bs genes, and the common ancestor of the other classes of genes) might have existed at the time of the Cambrian explosion. We also conducted a phylogenetic analysis of MADS-domain sequences from various species of plants and animals and presented a hypothetical scenario of the evolution of MADS-box genes in plants and animals, taking into account paleontological information. Our study supports the idea that there are two main evolutionary lineages (type I and type II) of MADS-box genes in plants and animals.     

Promoter analysis of MADS-box genes in eudicots through phylogenetic footprinting

The MIKC MADS-box gene family has been shaped by extensive gene duplications giving rise to subfamilies of genes with distinct functions and expression patterns. However, within these subfamilies the functional assignment is not that clear-cut, and considerable functional redundancy exists. One way to investigate the diversity in regulation present in these subfamilies is promoter sequence analysis. With the advent of genome sequencing projects, we are now able to exert a comparative analysis of Arabidopsis and poplar promoters of MADS-box genes belonging to the same subfamily. Based on the principle of phylogenetic footprinting, sequences conserved between the promoters of homologous genes are thought to be functional. Here, we have investigated the evolution of MADS-box genes at the promoter level and show that many genes have diverged in their regulatory sequences after duplication and/or speciation. Furthermore, using phylogenetic footprinting, a distinction can be made between redundancy, neo/nonfunctionalization, and subfunctionalization.     

甘蓝型油菜MADS-box基因家族的鉴定与系统进化分析

MADS-box基因家族参与调控开花时间、花器官分化、根系生长、分生组织分化、子房和配子发育、果实膨大及衰老等植物生长发育的重要过程。基于甘蓝型油菜(Brassica napus)基因组测序数据,利用生物信息学方法对甘蓝型油菜MADS-box基因家族进行鉴定和注释及基因结构与系统进化分析。结果显示,在甘蓝型油菜中鉴定出307个MADS-box基因家族成员,根据进化关系可将其分为两大类型,I型(M-type)包含α、β、γ三个亚家族,II型(MIKC-type)包括MIKCC和MIKC*两个亚家族,MIKCC可进一步分为13个小类;甘蓝型油菜A基因组染色体上分布的MADS-box基因多于C基因组。在基因结构上,MIKC-type亚家族基因序列普遍比M-type长且含有较多的外显子;M-type亚家族蛋白序列中的motif数量为2–5个,MIKC-type亚家族蛋白序列中平均含有7个motif。拟南芥(Arabidopsis thaliana)与甘蓝型油菜MADS-box基因共线性分析结果显示,全基因组复制事件对MADS-box基因家族尤其是MIKC亚家族的扩张起重要作用;MIKC亚家族基因在进化过程中受到的选择压力约为M-type的2倍,这表明MIKC-type亚家族在进化过程中被选择性保留。     

MADS-box基因家族基因重复及其功能的多样性

基因的重复(duplication)及其功能的多样性(diversification)为生物体新的形态进化提供了原材料。MADS-box基因在植物(特别是被子植物)的进化过程中发生了大规模的基因重复事件而形成一个多基因家族。MADS-box基因家族的不同成员在植物生长发育过程中起着非常重要的作用,在调控开花时间、决定花分生组织和花器官特征以及调控根、叶、胚珠及果实的发育中起着广泛的作用。探讨MADS-box基因家族的进化历史有助于深入了解基因重复及随后其功能分化的过程和机制。本文综述了MADS-box基因家族基因重复及其功能分化式样的研究进展。     

A short history of MADS-box genes in plants

Evolutionary developmental genetics (evodevotics) is a novel scientific endeavor which assumes that changes in developmental control genes are a major aspect of evolutionary changes in morphology. Understanding the phylogeny of developmental control genes may thus help us to understand the evolution of plant and animal form. The principles of evodevotics are exemplified by outlining the role of MADS-box genes in the evolution of plant reproductive structures. In extant eudicotyledonous flowering plants, MADS-box genes act as homeotic selector genes determining floral organ identity and as floral meristem identity genes. By reviewing current knowledge about MADS-box genes in ferns, gymnosperms and different types of angiosperms, we demonstrate that the phylogeny of MADS-box genes was strongly correlated with the origin and evolution of plant reproductive structures such as ovules and flowers. It seems likely, therefore, that changes in MADS-box gene structure, expression and function have been a major cause for innovations in reproductive development during land plant evolution, such as seed, flower and fruit formation.     

谷子 MADS-box基因家族的鉴定和表达分析

MADS-box基因是真核生物中一类重要的转录因子,参与调控多项植物的生长发育过程。然而关于谷子穗发育的MADS-box基因研究比较少。本研究使用序列相似性检索,在Phytozome 13.0数据库中筛选并且鉴定出了68个谷子MADS家族成员,并对这些家族成员的物理化学性质、系统发育树、染色体定位、表达谱等进行了全面的分析。结果表明,谷子MADS家族成员在染色体上分布不均匀,可以分为5个亚族。通过组织特异性表达谱分析得到,多数MADS基因在穗中表达量要高于其他器官。此外利用转录组测序技术对发育初期的谷穗和成熟期的谷穗进行了转录组测序分析,筛选到数个与谷穗分生组织发育相关MADS-box基因。为进一步揭示MADS-box基因在谷子穗发育过程中的作用奠定了重要的基础。     

Genomewide Structural Annotation and Evolutionary Analysis of the Type I MADS-Box Genes in Plants

Abstract The type I MADS-box genes constitute a largely unexplored subfamily of the extensively studied MADS-box gene family, well known for its role in flower development. Genes of the type I MADS-box subfamily possess the characteristic MADS box but are distinguished from type II MADS-box genes by the absence of the keratin-like box. In this in silico study, we have structurally annotated all 47 members of the type I MADS-box gene family in Arabidopsis thaliana and exerted a thorough analysis of the C-terminal regions of the translated proteins. On the basis of conserved motifs in the C-terminal region, we could classify the gene family into three main groups, two of which could be further subdivided. Phylogenetic trees were inferred to study the evolutionary relationships within this large MADS-box gene subfamily. These suggest for plant type I genes a dynamic of evolution that is significantly different from the mode of both animal type I (SRF) and plant type II (MIKC-type) gene phylogeny. The presence of conserved motifs in the majority of these genes, the identification of Oryza sativa MADS-box type I homologues, and the detection of expressed sequence tags for Arabidopsis thaliana and other plant type I genes suggest that these genes are indeed of functional importance to plants. It is therefore even more intriguing that, from an experimental point of view, almost nothing is known about the function of these MADS-box type I genes.     

草莓果实MADS-box基因保守片段的克隆与序列分析

根据多种植物MADS-box基因保守区序列设计简并引物,应用PCR技术从草莓绿果中分高出33条MADS-box基因cDNA片段.序列分析表明,这些片段长度在137 - 146 bp之间,包含基因起始密码子.推导的氨基酸序列与已登录的草莓的MADS-box基因同源性超过87％.推导的氨基酸序列与已知的革莓和其他物种调控果实发育成熟的MADs-box基因以及拟南芥的MADS-box家族基因进行系统发育分析,可将这些基因片段分科归入拟南芥MADS-box基因不同亚家族中,证明草莓果实中存在各类MADS-box家族基因,克隆的部分片段可能参与调控果实发育和成熟软化的调节.