高等植物离体受精研究进展

高等植物的卵细胞深藏在子房内的胚珠体细胞组织中,形成了对高等植物受精过程研究的技术障碍。以前采用超微结构观察研究受精过程已取得了一定的结果,但用固定切片技术研究受精机理需将卵细胞杀死,并且不能进行定点追踪观察。将高等植物的精、卵细胞分离出来在体外诱导其融合的离体受精技术可在很大程度上克服这些技术障碍,对雌、雄配子的识别和融合,合子开始胚胎发生等一系列的受精和胚胎发生机理进行研究。分离的雌、雄配子及合子使应用分子生物学方法研究这些细胞的结构和功能成为可能。将合子的二倍性和胚胎发生特性与外源DNA转入技术结合起来可使转基因植物研究的后期工作简单化。另外,异种植物离体精、卵细胞融合和杂种合子的培养也是进行远缘杂交的一条有潜力的途径。     

Imaging fertilization in flowering plants, not so abominable after all

Although the discovery of double fertilization in flowering plants took place at the end of the nineteenth century little progress had been made in understanding the cellular and molecular mechanisms involved until the end of the twentieth century. After attempts to study fertilization with isolated male and female gametes, researchers turned to Arabidopsis thaliana as a model for genetic analysis and in vivo imaging. The development of confocal imaging and fluorescent proteins, coupled with new molecular insights into cell fate specification of plant gametes, allowed the development of robust markers for cells participating in double fertilization. These markers enabled the imaging of double fertilization in vivo in Arabidopsis. These studies have been coupled with the identification and molecular characterization of genes controlling fertilization in Arabidopsis. Live imaging has already provided new insights on sperm cell delivery, the equivalence of the fate of the sperm cells, gamete fusion, and re-initiation of the zygotic life. This review covers these topics and outlines many important aspects of double fertilization that remain unknown.     

Female control of male gamete delivery during fertilization in Arabidopsis thaliana

Fertilization in both animals and plants relies on the correct targeting of the male gametes to the female gametes. In flowering plants, the pollen tube carries two male gametes through the maternal reproductive tissues to the embryo sac, which contains two female gametes. The pollen tube then releases its two male gametes into a specialized receptor cell of the embryo sac, the synergid cell. The mechanisms controlling this critical step of gamete delivery are unknown. Here, data based on the new sirène (srn) mutant of Arabidopsis thaliana provide the first evidence for female control over male gamete delivery. Live imaging of fertilization shows that wild-type pollen tubes do not stop their growth and do not deliver their contents in srn embryo sacs.     

Live-cell imaging reveals the dynamics of two sperm cells during double fertilization in Arabidopsis thaliana

Flowering plants have evolved a unique reproductive process called double fertilization, whereby two dimorphic female gametes are fertilized by two immotile sperm cells conveyed by the pollen tube. The two sperm cells are arranged in tandem with a leading pollen tube nucleus to form the male germ unit and are placed under the same genetic controls. Genes controlling double fertilization have been identified, but whether each sperm cell is able to fertilize either female gamete is still unclear. The dynamics of individual sperm cells after their release in the female tissue remain largely unknown. In this study, we photolabeled individual isomorphic sperm cells before their release and analyzed their fate during double fertilization in Arabidopsis thaliana. We found that sperm delivery was composed of three steps. Sperm cells were projected together to the boundary between the two female gametes. After a long period of immobility, each sperm cell fused with either female gamete in no particular order, and no preference was observed for either female gamete. Our results suggest that the two sperm cells at the front and back of the male germ unit are functionally equivalent and suggest unexpected cell-cell communications required for sperm cells to coordinate double fertilization of the two female gametes.     

Double fertilization - caught in the act

In flowering plants, fertilization is unique because it involves two pairs of male and female gametes, a process known as double fertilization. Here, we provide an overview of the field and a detailed review of the outstanding recent advances, including in vivo imaging of double fertilization and the identification of a signaling pathway controlling the release of the male gametes and of a protein involved in gamete membrane fusion. These recent results are stepping stones for further research; our knowledge of double fertilization is expanding as newly discovered molecular pathways are explored and new mutants are characterized. Controlling plant fertilization is essential for seed production, and molecular understanding of double fertilization will provide the tools to improve crops and breeding programs.     

离体受精作为技术平台在被子植物有性生殖研究中的应用

被子植物的离体受精10a前在玉米中已获得成功,尽管目前只在玉米获得完全成功和小麦获得部分成功,但离体受精技术的研究成果非常显著。目前离体受精技术已被用于其他的研究,如用分离的精细胞和卵细胞筛选配子细胞的特异基因和蛋白质：研究合子细胞被激活的机理：用不同种植物的精、卵细胞体外融合进行新的远缘杂交尝试;利用合子细胞易分裂和胚胎发生特征探索用其作为转基因研究的受体细胞等。以离体受精技术为基础在高等植物发育生物学和生殖生物学领域的基础研究和应用探索显示了巨大潜力。介绍了离体受精技术在被子植物有性生殖的研究成果和应用前景,为研究和利用被子植物有性生殖过程中的生殖细胞特征提供线索。     

Epigenetic reprogramming in plant reproductive lineages

Monoecious flowering plants produce both microgametophytes (pollen) and megagametophytes (embryo sacs) containing the male and female gametes, respectively, which participate in double fertilization. Much is known about cellular and developmental processes giving rise to these reproductive structures and the formation of gametes. However, little is known about the role played by changes in the epigenome in dynamically shaping these defining events during plant sexual reproduction. This has in part been hampered by the inaccessibility of these structures-especially the female gametes, which are embedded within the female reproductive tissues of the plant sporophyte. However, with the recent development of new cellular isolation technologies that can be coupled to next-generation sequencing, a new wave of epigenomic studies indicate that an intricate epigenetic regulation takes place during the formation of male and female reproductive lineages. In this mini review, we assess the fast growing body of evidence for the epigenetic regulation of the developmental fate and function of plant gametes. We describe how small interfereing RNAs and DNA methylation machinery play a part in setting up unique epigenetic landscapes in different gametes, which may be responsible for their different fates and functions during fertilization. Collectively these studies will shed light on the dynamic epigenomic landscape of plant gametes or 'epigametes' and help to answer important unresolved questions on the sexual reproduction of flowering plants, especially those underpinning the formation of two products of fertilization, the embryo and the endosperm.     

Nuclear DNA replicates during zygote development in Arabidopsis and Torenia fournieri

The progression of the cell cycle is continuous in most cells, but gametes (sperm and egg cells) exhibit an arrest of the cell cycle to await fertilization to form a zygote, which then continues through the subsequent phases to complete cell division. The phase in which gametes of flowering plants arrest has been a matter of debate, since different phases have been reported for the gametes of different species. In this study, we reassessed the phase of cell-cycle arrest in the gametes of two species, Arabidopsis (Arabidopsis thaliana) and Torenia fournieri. We first showed that 4’, 6-diamidino-2-phenylindole staining was not feasible to detect changes in gametic nuclear DNA in T. fournieri. Next, using 5-ethynyl-2’-deoxyuridine (EdU) staining that detects DNA replication by labeling the EdU absorbed by deoxyribonucleic acid, we found that the replication of nuclear DNA did not occur during gamete development but during zygote development, revealing that the gametes of these species have a haploid nuclear DNA content before fertilization. We thus propose that gametes in the G1 phase participate in the fertilization event in Arabidopsis and T. fournieri.

The replication of nuclear DNA does not occur during gamete development but during zygote development.     

Molecular repertoire of flowering plant male germ cells

Sperm cells—the male gametes of flowering plants—constitute the male founding lineage of angiosperms, possessing the unique capacity to fuse with the egg and central cells during double fertilization. Although it is well established that these cellular fusions are involved with initiating the development of the seedling-forming zygote and the endosperm that nourishes it, considerable information will be needed to characterize the full male molecular repertoire, which includes expressed genes of the male lineage, encoded proteins, and regulatory elements controlling male germ line identity, as well as male molecules that may mediate interactions with the female partner that initiate fertilization and development. Progress is being made using increasingly sensitive molecular methods to uncover important genes. With the pace of this discovery rapidly increasing, the likely outcome is that key molecules will be discovered within the next several years that control the founding cells of the embryo and endosperm and are involved in directing early development. Further insights into the genes and gene pathways that regulate male germ line differentiation will advance not only our fundamental understanding of these reproductive cells, but also the nature of cell–cell recognition, membrane fusion, double fertilization, zygote activation, early plant development and may aid our understanding of factors that have contributed to the overwhelming evolutionary success of flowering plants.     

A one‐step rectification of sperm cell targeting ensures the success of double fertilization

Successful fertilization in animals depends on competition among millions of sperm cells, whereas double fertilization in flowering plants usually involves just one pollen tube releasing two immobile sperm cells. It is largely a mystery how the plant sperm cells fuse efficiently with their female targets within an embryo sac. We show that the initial positioning of sperm cells upon discharge from the pollen tube is usually inopportune for gamete fusions and that adjustment of sperm cell targeting occurs through release and re-adhesion of one sperm cell, while the other connected sperm cell remains in stagnation.This enables proper adhesion of each sperm cell to a female gamete and coordinates the gamete fusions. Our findings reveal inner embryo sac dynamics that ensure the reproductive success of flowering plants and suggest a requirement for sperm cell differentiation as the basis of double fertilization.     

Gamete attachment process revealed in flowering plant fertilization

Sex-possessing organisms perform sexual reproduction, in which gametes from different sexes fuse to produce offspring. In most eukaryotes, one or both sex gametes are motile, and gametes actively approach each other to fuse. However, in flowering plants, the gametes of both sexes lack motility. Two sperm cells (male gametes) that are contained in a pollen grain are recessively delivered via pollen tube elongation. After the pollen tube bursts, sperm cells are released toward the egg and central cells (female gametes) within an ovule (Fig. 1). The precise mechanism of sperm cell movement after the pollen tube bursts remains unknown. Ultimately, one sperm cell fuses with the egg cell and the other one fuses with the central cell, producing an embryo and an endosperm, respectively. Fertilization in which 2 sets of gamete fusion events occur, called double fertilization, has been known for over 100 y. The fact that each morphologically identical sperm cell precisely recognizes its fusion partner strongly suggests that an accurate gamete interaction system(s) exists in flowering plants.Open in a separate windowFigure 1.Illustration of the fertilization process in flowering plants. First, each pollen tube accesses an ovule containing egg and central cells. Next, the 2 sperm cells face the female gametes in the ovule after the pollen tube bursts. Finally, each sperm cell simultaneously fuses with either egg or central cell.     

In vitro fertilization as a tool for investigating sexual reproduction of angiosperms

In vitro fertilization (IVF) of isolated male and female gametes of flowering plants was first accomplished in the last decade. Successful isolation of male and female gametes, and culturing of in vitro zygotes to form new plants, is a prelude to the use of IVF for research into the cellular and molecular control of fertilization in higher plants and its application as a tool in biotechnology. Genes unique to male and female gametes and zygotes of higher plants, although currently incompletely characterized, are expected to permit direct molecular dissection of fertilization. By applying IVF and microculture to zygotes and endosperm obtained by both in vivo and in vitro methods, newly activated fusion products may be observed and manipulated in media where they are directly accessible to the techniques of molecular cell biology. IVF and zygote culture may also offer potential for creating new hybrid plants by fusing isolated gametes from different species to produce unique zygotes and ultimately plants that would be impossible to obtain using typical crossing techniques. Transformation and regeneration frequencies using IVF may also be high enough to avoid the necessity of adding controversial antibiotic and herbicide resistant genes to screen transformed products. This review describes advances using IVF in plant sexual reproduction and discusses its potential in the genetic improvement of flowering plants.     

Fertilization, embryonic development and oviductal environment: role of estrogen induced oviductal glycoprotein

Mammalian oviduct is the physiological site for sperm capacitation, gamete fertilization and early embryonic development. The secretory cells lining the lumen of the mammalian oviduct synthesize and secrete high molecular weight glycoprotein (OGP) in response to estrogen. The protein has been shown to interact with gametes and early embryo. Several key functions have been postulated particularly its role in pre-implantation events which would have far reaching implications in assisted reproductive technology and in the development of non-hormonal contraceptive vaccine. The intention of this article is to discuss the current status of the protein and analyze how far the postulated function of OGP has been borne out by the available data.     

Analyzing female gametophyte development and function: There is more than one way to crack an egg

In flowering plants, gametes are formed in specialized haploid structures, termed gametophytes. The female gametophyte is a few-celled structure that integrates such diverse functions as pollen tube attraction, sperm cell release, gamete fusion and seed initiation. These processes are realized by distinct cell types, which ensure reproductive success in a coordinated manner. In the past decade, much progress has been made concerning the molecular nature of the functions carried out by the different cell types. Here, we review recent work that has shed light on female gametophyte development and function with a particular focus on approaches that have led to the isolation of genes involved in these processes.     

Cell-cell communication during double fertilization

Double fertilization in flowering seed plants requires intercellular signaling events between many interacting partners. The four cell types of the seven-celled female gametophyte communicate with each other to establish and maintain their identity. They secrete signaling molecules to guide the male gametophyte and to mediate sperm cell discharge and transport towards the two female gametes (the egg and central cell). After fusion of the gametes, guidance signals have to be removed to prevent polyspermy, embryo and endosperm development is induced generating daughter cells or nuclear regions of a different fate, and cell death is induced in the surrounding ovular cells. Until recently, little was known about the molecular nature of the signaling molecules that are involved in these processes. Now, small secreted proteins and peptides have been identified as prime candidates mediating several of these communication events.