Double fertilization in Gnetum gnemon (Gnetaceae): its bearing on the evolution of sexual reproduction within the Gnetales and the anthophyte clade

The fertilization process in Gnetum is critical to our understanding of the evolution of sexual reproduction within the Gnetales, a monophyletic group of nonfiowering seed plants that are the closest living relatives to flowering plants. Although much is known about the fertilization process in Ephedra, which is basal within the Gnetales, little is known about sexual reproduction in the derived sister groups Gnetum and Welwitschia. Ovules of Gnetum gnemon were collected at various stages after hand pollination and processed for light, fluorescence, and electron microscopy. Approximately 5 d after pollination, pollen tubes reach sexually mature female gametophytes, which are coenocytic. At that time, a binucleate sperm cell is found within each pollen tube. Within 7 d of pollination, double fertilization events occur when each of two sperm nuclei released from a pollen tube fuses with a separate, undifferentiated female nucleus within the free nuclear female gametophyte, which lacks differentiated egg cells. The products of double fertilization are two viable zygotes; endosperm is not formed. The lack of differentiated egg cells in Gnetum gnemon is unparalleled among land plants and the documentation of a regularly occurring process of double fertilization is congruent with the hypothesis that a rudimentary process of double fertilization evolved in a common ancestor of angiosperms and Gnetales.     

GROWTH AND DEVELOPMENT OF THE MALE GAMETOPHYTE OF GINKGO BILOBA WITHIN THE OVULE (IN VIVO)

The mature male gametophyte of Ginkgo biloba can be divided into two regions: a large saccate structure that is suspended within the fertilization chamber above the archegonia, and a pervasive, highly branched haustorial system that ramifies through the intercellular air spaces of the apex of the nucellus. This morphology appears to differ in many ways from the simpler more typical male gametophytes of most other groups of seed plants. Growth and development of the male gametophyte of Ginkgo biloba were studied using computer reconstruction techniques to generate images of the gametophyte from data derived from serial sections through the ovule. These investigations reveal that morphological development of the male gametophyte of Ginkgo biloba is divided into three distinct phases: 1) Germination, characterized by an initial brief period of diffuse growth. This phenomenon has not been described for any other seed plant male gametophyte; 2) Initiation of tip growth and the formation of a tubular body, as typifies all seed plant male gametophytes. In Ginkgo, this is accompanied by a high degree of branching, giving rise to an extensively branched haustorial system; 3) Late swelling of the proximal unbranched portion of the gametophyte resulting in formation of the saccate structure that is characteristic of the mature gametophyte. This process appears to be very similar to late development in cycad male gametophytes. Thus, despite the seemingly anomalous morphology of the mature male gametophyte of Ginkgo biloba, specific patterns of growth and development are in many ways similar to growth processes expressed by the male gametophytes of some or all major groups of seed plants.     

THE DEVELOPMENT OF THE FEMALE GAMETOPHYTE OF EPIPACTIS (ORCHIDACEAE) AND ITS INFERENCE FOR REPRODUCTIVE ECOLOGY

The development of the female gametophytes of Epipactis atrorubens, E. helleborine, and E. palustris have been investigated using confocal scanning laser microscopy. These species have T-tetrads and eight-nucleate female gametophytes in common. The development of the female gametophyte is monosporic in accordance with the Polygonum type. Furthermore, the outer integument grows slowly and reaches to the middle of the inner integument, when the female gametophyte is mature. In the first two species, T-tetrads develop prior to anthesis, which may be correlated with autogamy. The development of the female gametophyte of E. palustris appears to be similar in plants from different localities.     

THE DEVELOPMENT AND REPRODUCTIVE MORPHOLOGY OF HALOSACCION AMERICANUM I. K. LEE (RHODOPHYTA,PALMARIALES)1

Halosaccion americanum, a member of Palmariaceae, was grown in culture from spores and the life history was critically examined by the use of scanning EM and light microscopy. A mature tetrasporangium of H. americanum produces four spores that germinate to form two male and two female gametophytes. The male gametophytes grow to maturity in approximately eight months and macroscopically resemble the tetrasporophyte. Following the first division of the tetraspore, the two-celled female gametophyte consists of a vegetative cell and a carpogonium with trichogynes. Fertilization is accomplished by spermatia from male plants of the preceding generation, as male plants of the same season are immature. Spermatia are formed in a continuous layer over the surface of the mature male gametophytes and, when released, are entrained in long strands of mucous. Spermatia adhere to and fuse with trichogynes and, nuclear fusions presumably follow. The carposporophyte is absent; the new tetrasporophyte develops directly from the fertilized carpogonium. Growth of the sporophyte eventually obliterates the female gametophyte, and development into a mature tetrasporophyte proceeds over a period of approximately eight months. The development of H. americanum, with its extremely abbreviated female gametophyte stage and direct development of the tetrasporophyte from the zygote, indicates that this rhodophyte has the same life history as reported for other members of the Palmariales.     

云贵水韭雌配子体发育及其濒危机制的研究

为了解云贵水韭(Isoetes yunguiensis)的生殖过程和濒危原因,采用人工培养获得其雌配子体,用半薄切片法观察雌配子体发育过程。结果表明,云贵水韭的大孢子萌发率约为26%;雌配子体异养,终生都在大孢子细胞壁内发育;颈卵器发育只有2枚颈沟细胞而无腹沟细胞。雌配子体发育停止在游离核时期、颈壁细胞数量偏少或排列紊乱、颈沟细胞异常、卵细胞凋亡等可能是导致生殖濒危的原因。同时,游离核是水韭生殖生物学研究和系统学研究的重要环节之一;缺失腹沟细胞可能是水韭类简化性进化的特征之一。     

PHOTOSYNTHESIS IN THE FEMALE GAMETOPHYTE OF GINKGO BILOBA

The female gametophyte of Ginkgo biloba is the only seed plant gametophyte known to contain chlorophyll. Measurements of photosynthetically active radiation (PAR) indicate that a gametophyte growing within an ovule can receive significant quantities of light (70 μmol photons m^–2 s^–1). Under the conditions of our experiments, whole gametophytes dissected free from ovules were capable of gross photosynthesis, but not net photosynthesis. On a dry wt basis, the maximum rate of carbon fixation under near saturating light intensities was 3.64 × 10^–3 μmol CO₂g^–1 s^–1. The unique ability of the female gametophyte of Ginkgo biloba to produce chlorophyll and engage in photosynthesis appears to result from its exposure to sufficient levels of light and a predisposition to react to this stimulus by the development of a functional photosynthetic apparatus.     

Cytokinin receptors in sporophytes are essential for male and female functions in Arabidopsis thaliana

Arabidopsis has three cytokinin receptors genes: CRE1, AHK2 and AHK3. Availability of plants that are homozygous mutant for these three genes indicates that cytokinin receptors in the haploid cells are dispensable for the development of male and female gametophytes. The triple mutants form a few flowers but never set seed, indicating that reproductive growth is impaired. We investigated which reproductive processes are affected in the triple mutants. Anthers of mutant plants contained fewer pollen grains and did not dehisce. Pollen in the anthers completed the formation of the one vegetative nucleus and the two sperm nuclei, as seen in wild type. The majority of the ovules were abnormal: 78% lacked the embryo sac, 10% carried a female gametophyte that terminated its development before completing three rounds of nuclear division, and about 12% completed three rounds of nuclear division but the gametophytes were smaller than those of the wild type. Reciprocal crosses between the wild type and the triple mutants indicated that pollen from mutant plants did not germinate on wild-type stigmas, and wild-type pollen did not germinate on mutant stigmas. These results suggest that cytokinin receptors in the sporophyte are indispensable for anther dehiscence, pollen maturation, induction of pollen germination by the stigma and female gametophyte formation and maturation.Key words: cytokinin, cytokinin receptor, female gametophyte, male gametophyte, stigma     

银杏雌雄配子体发育及胚胎形成的研究进展

银杏(Ginkgo biloba)是现存最古老的裸子植物之一, 其生殖过程表现出许多原始特征和独特性状, 长期以来备受国内外专家的关注。经过近100年的研究取得了显著成果: (1) 银杏雄配子体发育周期长, 经历了从平周分裂到斜背式分裂,并最终垂周分裂形成带有鞭毛的游动精子; (2) 银杏雌配子体发育经历较长的游离核期和细胞化期, 分化形成颈卵器母细胞并经平周分裂、垂周分裂和斜向分裂形成成熟的颈卵器(包括有4个颈细胞和1个卵细胞); (3) 推测其精细胞中的液泡状结构为受精过程中的遗传物质载体; (4) 原胚的形成经历了游离核期和细胞化期。该文针对国内外最新银杏生殖生物学方面的研究进展, 对银杏雌雄配子体发育、受精过程以及胚胎形成等方面进行较为系统全面的分析和总结, 为进一步的银杏生殖生物学研究提供有价值的参考资料。     

A role for LORELEI,a putative glycosylphosphatidylinositol‐anchored protein,in Arabidopsis thaliana double fertilization and early seed development

In plants, double fertilization requires successful sperm cell delivery into the female gametophyte followed by migration, recognition and fusion of the two sperm cells with two female gametes. We isolated a null allele (lre‐5) of LORELEI, which encodes a putative glycosylphosphatidylinositol (GPI)‐anchored protein implicated in reception of the pollen tube by the female gametophyte. Although most lre‐5 female gametophytes do not allow pollen tube reception, in those that do, early seed development is delayed. A fraction of lre‐5/lre‐5 seeds underwent abortion due to defect(s) in the female gametophyte. The aborted seeds contained endosperm but no zygote/embryo, reminiscent of autonomous endosperm development in the pollen tube reception mutants scylla and sirene. However, unpollinated lre‐5/lre‐5 ovules did not initiate autonomous endosperm development and endosperm development in aborted seeds began after central cell fertilization. Thus, the egg cell probably remained unfertilized in aborted lre‐5/lre‐5 seeds. The lre‐5/lre‐5 ovules that remain undeveloped due to defective pollen tube reception did not induce synergid degeneration and repulsion of supernumerary pollen tubes. In ovules, LORELEI is expressed during pollen tube reception, double fertilization and early seed development. Null mutants of LORELEI‐like‐GPI‐anchored protein 1 (LLG1), the closest relative of LORELEI among three Arabidopsis LLG genes, are fully fertile and did not enhance reproductive defects in lre‐5/lre‐5 pistils, suggesting that LLG1 function is not redundant with that of LORELEI in the female gametophyte. Our results show that, besides pollen tube reception, LORELEI also functions during double fertilization and early seed development.     

麦秆蹄盖蕨（Athyrium fallaciosum）配子体的发育规律及播种密度对配子体性别分化的影响

在组织培养条件下,对麦秆蹄盖蕨（Athyrium fallaciosum）配子体发育的连续过程进行了详细观察。结果表明:麦秆蹄盖蕨孢子为四面体型; 孢子萌发为书带蕨型（Vittaria-type）;原叶体发育为铁线蕨型（Adiantum-type）,成熟原叶体为对称的心形;精子器近圆球形,成熟颈卵器细长,常向原叶体基部倾斜或弯曲。常规播种条件下,发现麦秆蹄盖蕨配子体有雌配子体、雄配子体、雌雄同体配子体和无性配子体类型。配子体的性别随密度不同而呈现一定的变化趋势,雄配子体随密度增大呈上升趋势;雌配子体随密度增大先上升后下降;雌雄同体配子体和无性配子体随密度变化不大。雌配子体和雌雄同体配子体具颈卵器数目一般为10～15个;精子器数目随密度的增大逐渐减少,雄配子体中具有约50个精子器,雌雄同体配子体具有约20个精子器。     

不同环境因子对珍稀观赏蕨类金毛狗配子体性别分化的影响

金毛狗[Cibotium barometz(L.)J.Sm.]是珍稀观赏蕨类的重要类群,为国家二级重点保护野生植物。该研究以金毛狗孢子为试验材料,探究培养密度、外源赤霉素以及光质等不同环境因子对金毛狗配子体性别分化的影响,为金毛狗人工繁育和蕨类植物配子体性别决定机制研究提供技术支持。结果表明:(1)低配子体培养密度(1个/cm2和5个/cm2)有利于颈卵器和雌配子体形成,随着配子体培养密度增加,颈卵器平均数量及雌配子体比率下降,精子器平均数量以及雄配子体和两性配子体比例增加,但配子体培养密度过高(80个/cm2)会导致大量无性配子体产生。(2)不同配子体培养密度下,随着培养时间延长,两性配子体比率均有增加,且增加幅度基本一致。(3)外源GA4显著抑制颈卵器和雌配子体形成,并显著促进精子器和雄配子体形成;外源GA3对金毛狗配子体性别分化没有显著影响。(4)白光、红光、蓝光等不同光质对金毛狗配子体性别分化未产生显著影响,但会影响配子体的发育和形态建成。     

EARLY GAMETOPHYTE ONTOGENY OF GLEICHENIA BIFIDA (WILLD.) SPRENG.: PHYLOGENETIC AND ECOLOGICAL IMPLICATIONS

Past investigation of gametophyte ontogeny in Gleichenia bifida indicated that there was considerable plasticity in early developmental stages (spore germination to initiation of two-dimensional growth). Recent examination has shown that this early ontogeny is not so plastic and can be defined by a characteristic series of developmental stages. Cell divisions following germination result in a three-dimensional mass of cells which secondarily initiates the two-dimensional thallus. Early development as a three-dimensional mass correlates with other gametophyte and sporophyte features which indicate Gleichenia to be phylogenetically primitive. This pattern of early ontogeny may also be of adaptive significance in enabling the gametophytes to survive the environmental fluctuations of the exposed, bare-soil habitats which they colonize.     

Female gametophyte and early seed development in Peperomia (Piperaceae)

The evolution of female gametophyte development provides an example of how minor ontogenetic modifications can impact the functional biology of seeds. Mature Peperomia-type female gametophytes are normally depicted as 16-nucleate, nine-celled structures. However, recent ultrastructural data have demonstrated that many previous reports were incorrect, suggesting that our understanding of the Peperomia-type ontogeny is incomplete. In this investigation, female gametophyte and early seed development is described in Peperomia dolabriformis, P. jamesoniana, and P. hispidula. Nuclear positioning, nuclear division, and vacuole morphology are documented during the syncytial stages of development, and two mature female gametophyte cellular configurations are described. Endosperm ploidy is measured in each species using microspectrofluorometry. We conclude that a 10-celled construction is likely the most common cellular configuration in Peperomia and that a three-celled female gametophyte exists in P. hispidula. We also describe how developmental modifications of wall formation could produce the diverse cellular configurations observed throughout Peperomia. Interestingly, the onset of female gametophyte diversification within Piperales correlates with the origin of the perisperm in the common ancestor of Piperaceae + Saururaceae. We posit that the origin of the perisperm may have relaxed selection on endosperm genetic constructs, thereby promoting diversification of female gametophyte ontogeny.     

Developmental and evolutionary hypotheses for the origin of double fertilization and endosperm.

The discovery of a second fertilization event that initiates endosperm in flowering plants, just over a century ago, stimulated intense interest in the evolutionary history and homology of endosperm, the genetically biparental embryo-nourishing tissue that is found only in angiosperms. Two alternative hypotheses for the origin of double fertilization and endosperm have been invoked to explain the origin of the angiosperm reproductive syndrome from a typical non-flowering seed plant reproductive syndrome. Endosperm may have arisen from a developmental transformation of a supernumerary embryo derived from a rudimentary second fertilization event that first evolved in the ancestors of angiosperms (endosperm homologous with an embryo). Conversely, endosperm may represent the developmental transformation of the cellular phase of non-flowering seed plant female gametophyte ontogeny that was later sexualized by the addition of a second fertilization event in a strongly progenetic female gametophyte (endosperm homologous with a female gametophyte). For the first time, explicit developmental and evolutionary transitions for both of these hypotheses are examined and compared. In addition, current data that may be congruent with either of these hypotheses are discussed. It is clear that much remains to be accomplished if the evolutionary significance of the process of double fertilization and the formation of endosperm is to be fully understood.     

Anatomy,microstructure, and endogenous hormone changes in Gnetum parvifolium during anthesis

The study of the sexual systems of plants is very important for understanding their evolutionary process. Gnetum is a pivotal species in comprehending the seed plant phylogeny. However, the sexual systems of this genus are not fully understood. To investigate the sexual system of Gnetum, the anatomical structure, microstructure, and endogenous hormones were investigated from the differentiation of flower buds to fertilization in the floral organs of female and male of G. parvifolium (Warb.) C.Y. Cheng, widely distributed in the north of China. After 2 years of field investigations, the staminate strobili were observed on female plants for the first time and the abortive ovules were also found on male plants. In addition, high levels of gibberellin A₃ and zeatin riboside led to masculinization, whereas a high level of indole‐3‐acetic acid favored feminization. A comprehensive analysis of the results indicates that G. parvifolium may not be completely dioecious on morphology, but female and male plants can only perform their own gender function, which would provide a better understanding of the diversity of sexual systems in Gnetum, and reproductive structures of seed plants.     

毛叶粉背蕨配子体的泌粉现象及其系统学意义

为探讨蕨类配子体泌粉现象的系统学意义,对5种粉背蕨属(Aleuritopteris)植物的配子体发育过程进行了观察。结果表明,毛叶粉背蕨(A.squamosa)的配子体(通常是雌配子体)也具有泌粉现象,而其他4种的配子体不具粉状分泌物。基于叶绿体rbc L序列的证据表明,毛叶粉背蕨与粉背蕨属其他植物、中国蕨属(Sinopteris)等构成一个具有强烈支持率的单系,即Hemionitids支,该支与美洲分布的隐囊蕨类互为姐妹群。因此,配子体泌粉现象在碎米蕨类中并非隐囊蕨类植物所特有,泌粉现象的产生,在系统发育上至少涉及2次独立的演化事件。毛叶粉背蕨的泌粉现象多发生在雌性配子体上,暗示配子体的泌粉可能与配子体的雌性分化和胚发生发育相关。     

The evolution of embryogeny in seed plants and the developmental origin and early history of endosperm

For almost a century, the formation of endosperm from a second and distinctive fertilization event has been viewed as a unique feature of flowering plants. However, until recently, the evolutionary origin of this unique embryo-nourishing entity remained a mystery. Based upon comparative developmental analysis of reproduction among basal angiosperms and their closest extant relatives, the Gnetales (Ephedra, Gnetum, and Welwitschia), it is possible to construct an explicit hypothesis of the events that led to the evolutionary establishment of double fertilization and endosperm. The formulation of this historical record is derived entirely from and dependent upon the determination of reproductive features that are likely to have characterized the common ancestors of angiosperms and Gnetales. Current evidence is most congruent with the concept that a process of double fertilization first evolved in a common ancestor of the Gnetales and angiosperms. Initially, however, the second fertilization product was diploid and yielded a supernumerary embryo. Subsequent to the divergence of the angiosperm lineage from its closest relatives (which include the Gnetales), modification of the development of the supernumerary embryo (derived from the second fertilization event) led to the establishment of an embryo-nourishing endosperm. Comparative analysis of patterns of embryogeny within Gnetales and angiosperms establishes that embryo development in the ancestors of flowering plants (with a rudimentary process of double fertilization) was ab initio cellular, and not free nuclear, as had previously been assumed. Thus, it is likely that the earliest flowering plants displayed an ab initio cellular pattern of endosperm development, whose expression was inherited from that of the supernumerary embryo of the ancestors of flowering plants.