Morphological analysis of female gametophyte development in the bel1 stk shp1 shp2 mutant

Abstract

In Arabidopsis thaliana, cell fate in developing ovules is determined by the action of the homeodomain factor BELL1 (BEL1) and of the MADS-box factors SEEDSTICK (STK), SHATTERPROOF1 (SHP1) and SHP2. The analysis of the bel1 and the stk shp1 shp2 mutants revealed that the functional megaspore is formed, however, it does not proceed into megagametogenesis. In the bel1 stk shp1 shp2, quadruple mutant megasporogenesis does not take place. In this article we describe a detailed morphological analysis of the quadruple mutant, and we discuss the possibility that BELL1, STK, SHP1 and SHP2 not only control integument identity determination and development, but that they might also play a role during megasporogenesis.     

Nitrate and glutamate as environmental cues for behavioural responses in plant roots

As roots explore the soil, they encounter a complex and fluctuating environment in which the different edaphic resources (water and nutrients) are heterogeneously distributed in space and time. Many plant species are able to respond to this heterogeneity by modifying their root system development, such that they colonize the most resource-rich patches of soil. The complexities of these responses, and their dependence on the implied ability to perceive and integrate multiple external signals, would seem to amply justify the term 'behaviour'. This review will consider the types of behaviour that are elicited in roots of Arabidopsis thaliana by exposure to variations in the external concentrations and distribution of two different N compounds, nitrate and glutamate. Molecular genetic studies have revealed an intricate N regulatory network at the root tip that is responsible for orchestrating changes in root growth rate and root architecture to accommodate variations in the extrinsic and intrinsic supply of N. The review will discuss what is known of the genetic basis for these responses and speculate on their physiological and ecological significance.     

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。     

Cloning and characterization of PhPI9 involved in floral development from Phalaenopsis Orchid

In the attempt to discover new genes involved in the floral development in monoeotyledonousin species,we have cloned and characterized the homologous PISTALLATA-like (PI-like) gone from Phalaenopsis hybrid cultivar named PhPI9 (Phalaenopsis PI STILLATA # 9).The eDNA of PhPI9 has a fragment of 834 bp and has 60% identity with the PISTILATA from Arabidopsis.The deduced amino acid sequence of PhPI9 had the typical PI-motif.It also formed a subelade with other monoeot PI-type genes in phylogenetie analysis.Southern analysis showed that PhPI9 was present in the Phalaenopsis orchid genome as a single copy.Furthermore,it was expressed only in the lip of the Phalaenopsis flower and no expression was detected in vegetative organs.Thus,as a B-function MADS-box gone,PhP19 specifies floral organ identity in orchids.     

Temporal and Spatial Requirement of EMF1 Activity for Arabidopsis Vegetative and Reproductive Development

EMBRYONIC FLOWER （EMF） genes are required to maintain vegetative development via repression of flower homeotic genes in Arabidopsis. Removal of EMF gene function caused plants to flower upon germination, producing abnormal and sterile flowers. The pleiotropic effect of ernfl mutation suggests its requirement for gene programs involved in diverse developmental processes. Transgenic plants harboring EMF1 promoter：：glucuronidase （GUS） reporter gene were generated to investigate the temporal and spatial expression pattern of EMF1. These plants displayed differential GUS activity in vegetative and flower tissues, consistent with the role of EMF1 in regulating multiple gene programs. EMFI：：GUS expression pattern in emf mutants suggests organ-specific auto-regulation. Sense- and antisense （as） EMF1 cDNA were expressed under the control of stage- and tissue-specific promoters in transgenic plants. Characterization of these transgenic plants showed that EMF1 activity is required in meristematic as well as differentiating tissues to rescue emf mutant phenotype. Temporal removal or reduction of EMF1 activity in the embryo or shoot apex of wild-type seedlings was sufficient to cause early flowering and terminal flower formation in adult plants. Such reproductive cell memory is reflected in the flower MADS-box gene activity expressed prior to flowering in these early flowering plants. However, temporal removal of EMF1 activity in flower meristem did not affect flower development. Our results are consistent with EMF1＇s primary role in repressing flowering in order to allow for vegetative growth.     

K-Box Sequence of the Apetala1-Class MADS-Box Genes in Hexaploid Wheat

Direct amplification of genomic DNA from four wheat species produced DNA fragments corresponding to the K-box sequence of the apetala1/squamosa class of the MADS-box genes. Exons 3 to 5 were highly conserved within the tribe Triticeae and very similar to the apetala1 genes of darnel ryegrass, rice, and maize. Most of the variations observed were due to synonymous substitutions: the deduced amino acid sequences were 89–99% similar within the Triticeae and 88–94% within the entire family Poaceae. Introns 3 and 4 of the apetala1 class genes were similar in wheat and rye and differed from those in other MADS-box genes presently known.     

朵丽蝶兰 MADS-box 基因 DtpsMADS1 的克隆与表达特性简

植物MADS-box基因家族编码高度保守的转录因子,参与了包括花器官发育和开花在内的多种发育进程。为阐释兰科植物成花的分子调控机制,根据MADS-box基因保守序列设计简并引物,用RACE方法从朵丽蝶兰花葶中克隆到1个MADS-box家族基因,该基因cDNA全长960 bp,包含37 bp 5′UTR,一个738 bp的开放阅读框(ORF)和185 bp 3′UTR,共编码245个氨基酸。序列和系统进化树分析表明,该基因与其他植物的MADS-box基因具有很高的同源性,属于AP1/FUL-like亚家族,命名为DtpsMADS1,GeneBank登录号为JQ065097。实时荧光定量PCR检测结果显示：DtpsMADS1具有明显的组织表达特异性;在根和叶中,DtpsMADS1在花前期和花后期表达量较高;苗期和盛花期表达量较低;DtpsMADS1在花葶中的表达趋势与根和叶相似;而在花器官中,DtpsMADS1只有痕量表达。由此推断,DtpsMADS1可能参与开花进程调控,而不参与花器官的形态建成。     

A cDNA from grapevine (Vitis vinifera L.), which shows homology to AGAMOUS and SHATTERPROOF,is not only expressed in flowers but also throughout berry development

An AGAMOUS/SHATTERPROOF homologue (Vvmads1) was isolated from grapevine by differential display between berry and leaf mRNA. The predicted protein sequence of the full-length clone shows a high degree of homology to PLENA (77% identity) and to SHP1 and SHP2 (75% and 74% identity respectively), and is grouped with AGAMOUS/PLENA homologues when the conserved MADS and K domains are compared. Vvmads1 is expressed only in the later stages of flower development and throughout berry development, although expression is reduced after ripening commenced. When Vvmads1 was over-expressed in tobacco, the resulting plants display altered morphologies in the outer two floral whorls. In the most extreme cases, the inner whorls were surrounded by a carpelloid structure created by the modified sepals. Within these sepals were petals which had been split into sections and which were attached at the base of the flower by structures with the appearance of filaments. The results of this study suggest that Vvmads1 has a regulatory role in flower development before fertilisation and a role in fruit development after fertilisation.