植物MADS-box基因的研究进展

MADS-box基因是一类重要的转录调控因子,在动物、植物、真菌中都有分布。在植物中从根、茎、叶到花的发育,果实的成熟MADS-box基因都起作用,尤其是在开花植物中花的发育,开花时间的控制等方面起着重要的作用。综述了MADS-box基因的分类、进化、结构、以及MADS-box基因在植物花器官发育,开花时间的控制,果实的成熟等方面的作用。     

Overexpression of the cucumber LEAFY homolog CFL and hormone treatments alter flower development in gloxinia (Sinningia speciosa)

Leafy (LFY) and LFY-like genes control the initiation of floral meristems and regulate MADS-box genes in higher plants. The Cucumber-FLO-LFY (CFL) gene, a LFY homolog in Cucumis sativus L. is expressed in the primordia, floral primordia, and each whirl of floral organs during the early stage of flower development. In this study, functions of CFL in flower development were investigated by overexpressing the CFL gene in gloxinia (Sinningia speciosa). Our results show that constitutive CFL overexpression significantly promote early flowering without gibberellin (GA(3)) supplement, suggesting that CFL can serve functionally as a LFY homolog in gloxinia. Moreover, GA(3) and abscisic acid (ABA) treatments could modulate the expression of MADS-box genes in opposite directions. GA(3) resembles the overexpression of CFL in the expression of MADS-box genes and the regeneration of floral buds, but ABA inhibits the expression of MADS-box genes and flower development. These results suggest that CFL and downstream MADS-box genes involved in flower development are regulated by GA(3) and ABA.     

MADS-BOX GENES: DEVELOPMENT AND EVOLUTION OF PLANT BODY PLANS

We review functional data on MADS-box genes, recent phylogenetic analyses of these coding regions, and their roles in the development and evolution of key morphological innovations in plants. We map the origin of important morphological structures in particular diverse stages of the life cycle in different plant clades onto organismal phylogenies, and present relevant molecular genetic aspects of development related to the MADS-box genes. We focus on reproductive structures of the sporophyte because most functional characterizations have been done of MADS-box genes involved in flower development. We discuss MADS-box evolution in flowering plants, but we also review studies in the other nonflowering vascular plants, gymnosperms (conifers and gnetales), and ferns and preliminary data from the algae. We suggest that floral (e.g. flowering time, inflorescence, and flower meristem identity) MADS-box and nonfloral plant MADS-box genes should be the focus of future comparative research. Cloning and functional analyses of MADS-box genes in bryophytes, particularly in the experimental system Physcomitrella patens (Hedw.) B.S.G., are needed. The ABC model of floral organ specification is an excellent general representation of an important network of genes; however, formal analytical tools are required to integrate data on complex gene interaction in comparative analyses. This and other analytical approaches to constructing gene network models will help to frame homology hypotheses in an evolutionary and developmental framework.     

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.     

草原龙胆MADS-box基因的克隆及表达分析

植物MADS-box 基因家族编码高度保守的转录因子, 参与了包括花发育在内的多种发育进程。为阐释双子叶植物草原龙胆(Eustoma grandiflorum)花器官发育的分子调控机制, 根据MADS-box基因保守序列设计简并引物, 用3'-RACE方法从 草原龙胆中克隆了4个花器官特异表达的MADS-box家族基因。序列和系统进化树分析表明, 这4个基因分别与金鱼草DEF基因、矮牵牛FBP3基因和FBP6基因以及拟南芥SEP3基因具有很高的同源性, 分别属DEF/GLO、AG-like和SEP-l ike亚家族。从而将这4个基因分别命名为EgDEF1、EgGLO1、EgPLE1和EgSEP3-1。推导的氨基酸序列显示, 这些基因编码的蛋白质都包含高度保守的MADS结构域、I结构域和K结构域, 每个基因均有其亚家族特异的C-末端功能域。基因特异性RT-PCR检测结果显示: EgDEF1 在萼片、花瓣、雄蕊及胚珠中高丰度表达, 在心皮中微量表达; 而EgGLO1在花瓣和雄蕊中高丰度表达, 在萼片中微量表达; 在根、茎、叶等营养器官中均未检测到上述2个基因的表达。EgPLE1在雌蕊、心皮和胚珠中特异表达, 但表达的丰度存在差异, 在雄蕊中的表达有所减弱。SEP-like亚家族基因EgSEP3-1在四轮花器官和胚珠中均特异表达,且表达丰度相对一致。     

APETALA1 and SEPALLATA3 interact to promote flower development

In Arabidopsis, the closely related APETALA1 (AP1) and CAULIFLOWER (CAL) MADS-box genes share overlapping roles in promoting flower meristem identity. Later in flower development, the AP1 gene is required for normal development of sepals and petals. Studies of MADS-domain proteins in diverse species have shown that they often function as heterodimers or in larger ternary complexes, suggesting that additional proteins may interact with AP1 and CAL during flower development. To identify proteins that may interact with AP1 and CAL, we used the yeast two-hybrid assay. Among the five MADS-box genes identified in this screen, the SEPALLATA3 (SEP3) gene was chosen for further study. Mutations in the SEP3 gene, as well as SEP3 antisense plants that have a reduction in SEP3 RNA, display phenotypes that closely resemble intermediate alleles of AP1. Furthermore, the early flowering phenotype of plants constitutively expressing AP1 is significantly enhanced by constitutive SEP3 expression. Taken together, these studies suggest that SEP3 interacts with AP1 to promote normal flower development.