枸杞雌、雄配子DNA含量与细胞周期变化的初步研究

枸杞是二胞花粉植物。花粉在柱头上萌发后生殖细胞在花粉管中分裂形成精细胞。在花粉管中,精细胞开始合成DNA,随着花粉管生长,精细胞DNA含量持续增加。当花粉管在退化助细胞中破裂,释放出的2个精细胞DNA含量达到1．92倍（1．92C）。在开花当天,卵细胞已合成了约1／3DNA,并持续增加。开花后30h,卵细胞中的DNA含量达到1．63C。在受精前,卵细胞中的DNA含量达到1．83C。精、卵细胞融合后,合子DNA含量为3．53C。去雄排除花粉管影响后,己合成1／5DNA的过熟卵细胞停止合成,表明卵细胞持续合成DNA需要花粉管的刺激。枸杞雌、雄配子在融合前合成DNA,在细胞周期的G,期发生融合,属于G2类型。     

Relationship between double fertilization and the cell cycle in male and female gametes of tobacco

Nuclear DNA content of male and female gametes of tobacco was determined using 4,6-diamindino-2-phenylindole and quantitative microfluorimetry. Pollen grains are released with generative cells containing 2C DNA. Mitotic division occurs in the pollen tube 8–12 h after germination. The resulting sperm cells have 1C DNA content during pollen tube elongation in the style. Sperm cells deposited in the degenerated synergid have a DNA content between 1C and 2C, indicating that sperm are in S-phase in the synergid. Concomitant with pollen tube arrival, the egg cell increases in DNA quantity from 1C to between 1C and 2C at 48 h after pollination. In the absence of pollination, S-phase in the egg cell is delayed by up to 36 h. Newly formed zygotes contain nuclear DNA concentrations of 4C at karyogamy and remain at 4C until zygote division. Tobacco displays cell fusion after the completion of S-phase, apparently during G₂. Failure to achieve an optimized system for in vitro fertilization in Nicotiana may reflect the challenges of achieving cell cycle synchrony in gametes isolated from pollen tubes. Receptive gametes are presumably those that pass through the protracted S-phase, reaching G₂ receptivity and cell cycle congruity before fusion.     

烟草雌、雄配子DNA含量变化

采用显微分光光度法测定了烟草（Nieotiana tabacum）精细胞和卵细胞的DNA含量。烟草是二胞花粉,花粉萌发后生殖细胞在花粉管中分裂形成精细胞。授粉后45h花粉管到达子房,在花粉管内的精细胞DNA含量为1C。当花粉管在退化助细胞中破裂,释放出的两个精细胞开始合成DNA。在与卵细胞融合前,两个精细胞DNA含量接近2C。随着精细胞的到达及合成DNA,卵细胞也开始合成DNA,融合前的卵细胞DNA含量也接近2C。精、卵细胞融合后,合子DNA含量为4C。烟草雌、雄配子是在细胞周期的G2期发生融合,属于G2型。     

烟草雌、雄配子DNA 含量变化

采用显微分光光度法测定了烟草( Nicotiana tabacum) 精细胞和卵细胞的DNA 含量。烟草是二胞花粉, 花粉萌发后生殖细胞在花粉管中分裂形成精细胞。授粉后45 h 花粉管到达子房, 在花粉管内的精细胞DNA 含量为1C。当花粉管在退化助细胞中破裂, 释放出的两个精细胞开始合成DNA。在与卵细胞融合前,两个精细胞DNA 含量接近2C。随着精细胞的到达及合成DNA, 卵细胞也开始合成DNA, 融合前的卵细胞DNA 含量也接近2C。精、卵细胞融合后, 合子DNA 含量为4C。烟草雌、雄配子是在细胞周期的G2 期发生融合, 属于G2 型。     

The kinetics of cytological events during double fertilization in Zea mays L.

By using a clearing method, the process of double fertilization in Zea mays L. (line A 188) was analysed and the precise sequence of events was determined. The period from pollen tube arrival to gamete fusion was relatively short, possibly less than 1 h. The karyogamy was of premitotic type, and the time from the contact of male and female nuclei to the fusion of male and female nucleoli was about 5 h in the egg cell and 3 h in the central cell. In the central cell, the sperm nucleus fused with either one of the polar nuclei or the secondary nucleus, the latter being observed for the first time in maize. The zygote was in the resting period for 13–16 h before division commenced, changing the cell polarity during karyogamy and the resting period. The primary endosperm nucleus divided immediately after karyogamy was completed in the central cell. The embryo sacs with two-celled proembryos contained four to eight endosperm nuclei. The timetable of fertilization events could be a standard for further studies on in vitro fertilization at the cytological and molecular levels.     

Centenary on S.G.Nawaschin's Discovery of Double Fertilization: Retrospects and Prospects

A review on the double fertilization in angiosperm is addressed at its centennial discovery by S.G. Nawaschen. Studies in the first 50 years mainly by light microscopy had defined this process of double fertilization as a general characteristic in angiosperms. In the later 50 years research works in this field have been greatly advanced on account of the developing new techniques especially the electron-microscopy. The topics in this review include: (1) The growth of pollen tube entering the embryo sac: role of the synergid in the pollen tube receiption and signals from the degenerated synergid. (2) The arrival of male gametes to female gametes: structure and function of the male germ unit, the function of cytoskeleton in the delivery of sperm cells. (3) Gametic fusion: the structure and function of the female germ unit, gametic membrane fusion, karyogamy, DNA contents in sperm and egg nuclei, the relationship between the karyogamy and cell cycle, sperm dimorphism and preferential fertilization, and spermegg recognition. Future directions for the research of double fertilization are also recommended.     

Nuclear DNA amount during sporogenesis and gametogenesis in sexual and aposporous buffelgrass

Nuclear DNA amounts (C values) were measured in Feulgen-stained sections of anthers and ovules of sexual plant B-2s (genotype aaaa) and aposporous cultivar Higgins (genotype AAaa) of buffelgrass (Pennisetum ciliare). The mass of the unreplicated nuclear genome of a gamete equals 1C DNA. In both lines, pollen mother cell nuclei were 4C before leptotene; anther wall, dyad, 1-nucleate pollen, and generative cell nuclei were 2C; microspore tetrad, enlarging microspore, and sperm nuclei were 1C. The tapetum persisted as uninucleate cells with 4C DNA. Archespores (2-4C) of both lines initiated meiosis to form megaspore tetrad nuclei with 1-2C DNA. In B-2s, chalazal megaspores (2-4C) formed reduced 8-nucleate Polygonum type embryo sacs, and sacs at 2- and 4-nucleate stages showed distributions with peaks near C1 and C2, corresponding to G1 and G2 cell cycle phases; this is characteristic of active mitosis. Nuclei of 8-nucleate sacs and of eggs and polars were 1C, indicating chromosomes were not duplicated before fertilization. Antipodal nuclei had levels from 1 to 36C, possibly due to polyteny or endopolyploidy. In Higgins, aposporous initials and 2-nucleate embryo sacs showed bimodal distributions of 2n nuclei with peaks at 2C and 4C DNA. Nuclei of newly formed 4-nucleate Panicum type aposporous sacs and of polars were 2C; aposporous eggs stained too faintly for reliable measurement.Names of products are included for the benefit of the reader and do not imply endorsement or preferential treatment by USDA     

KARYOGAMY BLOCK BY HEAT STRESS IN THE FERTILIZATION OF BROWN ALGAE

Karyogamy was inhibited by heat stress in zygotes of Scytosiphon lomentaria (Lyngbye) Link (isogamy), Cutleria cylindrica Okamura (anisogamy), and Fucus distichus subsp. evanescens (C. Agardh) Powell (oogamy). Although high temperatures did not inhibit migration of the male and female nuclei, nuclear envelope fusion was blocked. The ultrastructural stage at which karyogamy was inhibited varied among these species. In S. lomentaria, the outer membranes fused with each other, but the inner membranes did not fuse. Partial fusion of the nuclear envelope occurred in C. cylindrica. In F. distichus, the block of karyogamy at high temperature was incomplete, and nuclear fusion proceeded gradually. The block to karyogamy in S. lomentaria zygotes was reversible, and karyogamy proceeded when zygotes were transferred from 22° to 14° C. Experiments using inhibitors suggested that proteins that might be formed de novo after fertilization do not participate in karyogamy or its inhibition at either 14° or 22° C.     

Nuclear DNA synthesis during the induction of embryogenesis in cultured microspores and pollen of Brassica napus L.

The dynamics of nuclear DNA synthesis were analysed in isolated microspores and pollen of Brassica napus that were induced to form embryos. DNA synthesis was visualized by the immunocytochemical labelling of incorporated Bromodeoxyuridine (BrdU), applied continuously or as a pulse during the first 24 h of culture under embryogenic (32 °C) and non-embryogenic (18 °C) conditions. Total DNA content of the nuclei was determined by microspectrophotometry. At the moment of isolation, microspore nuclei and nuclei of generative cells were at the G1, S or G2 phase. Vegetative nuclei of pollen were always in G1 at the onset of culture. When microspores were cultured at 18 °C, they followed the normal gametophytic development; when cultured at 32 °C, they divided symmetrically and became embryogenic or continued gametophytic development. Because the two nuclei of the symmetrically divided microspores were either both labelled with BrdU or not labelled at all, we concluded that microspores are inducible to form embryos from the G1 until the G2 phase. When bicellular pollen were cultured at 18 °C, they exhibited labelling exclusively in generative nuclei. This is comparable to the gametophytic development that occurs in vivo. Early bicellular pollen cultured at 32 °C, however, also exhibited replication in vegetative nuclei. The majority of vegetative nuclei re-entered the cell cycle after 12 h of culture. Replication in the vegetative cells preceded division of the vegetative cell, a prerequisite for pollen-derived embryogenesis.     

Detection of changes in the nuclear phase and evaluation of male germ units by flow cytometry during in vitro pollen tube growth in <Emphasis Type="Italic">Alstroemeria aurea</Emphasis>

This study aimed to analyze male gamete behavior from mature pollen to pollen tube growth in the bicellular pollen species Alstroemeria aurea. For mature pollen, pollen protoplasts were examined using flow cytometry. The protoplasts showed two peaks of DNA content at 1C and 1.90C. Flow cytometry at different developmental stages of pollen tubes cultured in vitro revealed changes in the nuclear phase at 9 and 18 h after culture. Sperm cell formation occurred at 6–9 h after culture, indicating that the first change was due to the division of the generative cells into sperm cells. After sperm cell formation, the number of vegetative nucleus associations with sperm cells showed a tendency to increase. This association was suggested as the male germ unit (MGU). When sperm cells, vegetative nuclei, and partial MGUs were collected separately from pollen tubes cultured for 18 h and analyzed using a flow cytometer, the sperm cells and vegetative nuclei contained 1C DNA, while the DNA content of partial MGUs was counted as 2C. Therefore, the second change in the nuclear phase, which results in an increase in 2C nuclei, is possibly related to the formation of MGUs.     

A novel class of MYB factors controls sperm-cell formation in plants

In contrast to animals, the plant male germline is established after meiosis in distinctive haploid structures, termed pollen grains. The germline arises by a distinct asymmetric division of the meiotic products . The fates of the resulting vegetative and generative cells are distinct. In contrast to the larger vegetative cell, arrested in the G1 phase of the cell cycle, the smaller generative cell divides once to produce the two male gametes or sperm cells. Sperm cells are delivered to the female gametes by the pollen tube, which develops from the vegetative cell. In spite of recent efforts to understand pollen development , the molecular pathway controlling sperm-cell ontogenesis is unknown. Here, we present the isolation of DUO1, a novel R2R3 MYB gene of Arabidopsis, as the first gene shown to control male gamete formation in plants. DUO1 is specifically expressed in the male germline, and DUO1 protein accumulates in sperm-cell nuclei. Mutations in DUO1 produce a single larger diploid sperm cell unable to perform fertilization. DUO1 appears to be evolutionarily conserved in several plant species and defines a new subfamily of pollen-specific MYB genes.     

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.     

Nuclear DNA amounts in the egg and zygote of maize (Zea Mays L.)

The nuclear DNA content of isolated eggs and zygotes of maize was estimated using 4,6-diamidino-2-phenylindole (DAPI) staining and microspectrofluorometry. The data indicate that egg nuclei contain the 1C level of DNA (basic haploid amount) at the time of karyogamy, and that, by inference, the sperm nuclei are also at 1C. Fertilization occurred in most ovules by 24–28 h post-pollination (hpp), and DNA synthesis was well underway by 27–31 hpp. By 30–34 hpp, 80% of the zygotes were at the 3C DNA level or above, and many were undergoing mitosis. This study provides information that is pertinent to experiments on the microinjection of exogenous DNA into isolated zygotes of maize, and it will serve as a comparative base for future determinations of the DNA content of zygotes produced and cultured in vitro.Abbreviations DAPI 4,6-diamidino-2-phenylindole - hpp hours post-pollination We would like to thank R. Blanc, D. Aldon, and C. Digonnet for their expert technical assistance and advice during the course of this study. Partial support for this study by the Organized Research Fund, Northern Arizona University, is gratefully acknowledged. The bulk of this study was carried out while H.L.M. was visiting research professor at the Ecole Normale Supérieure de Lyon.     

The cytology of the gametes and fertilization of Allomyces macrogynus

The gametes and the process of fertilization were examined by light and electron microscopy in the lower eukaryote Allomyces macrogynus. Differences in gamete morphology included the overall larger size and the presence of a larger nuclear apparatus, along with the association of a side-body complex and many more mitochondria in the female gamete. In this species of Allomyces, fertilization was initiated by contact and fusion of specialized regions of the gamete plasma membranes resulting in a binucleate fusion cell surrounded by plasma membrane contributed by both partners. Following plasmogamy, nuclear fusion was initiated by multiple nuclear membrane contacts between adjacent outer membranes. Following inner membrane fusion, small nucleoplasmic bridges were observed which presumably fused with one another and resulted in a single bridge which widened, forming the mature diploid nucleus. After karyogamy, fusion of the nuclear caps did not always occur and zygotes with and without fused caps were observed. Coalescence of the nucleoli completed the events of fertilization, forming a zygote with a single nuclear apparatus (sometimes with two caps) and two flagella. These observations are discussed in relation to fertilization mechanisms and compared to fertilization in other organisms.     

Cytoplasmic inheritance of organelles in brown algae

Brown algae, together with diatoms and chrysophytes, are a member of the heterokonts. They have either a characteristic life cycle of diplohaplontic alternation of gametophytic and sporophytic generations that are isomorphic or heteromorphic, or a diplontic life cycle. Isogamy, anisogamy and oogamy have been recognized as the mode of sexual reproduction. Brown algae are the characteristic group having elaborated multicellular organization within the heterokonts. In this study, cytoplasmic inheritance of chloroplasts, mitochondria and centrioles was examined, with special focus on sexual reproduction and subsequent zygote development. In oogamy, chloroplasts and mitochondria are inherited maternally. In isogamy, chloroplasts in sporophyte cells are inherited biparentally (maternal or paternal); however, mitochondria (or mitochondrial DNA) derived from the female gamete only remained during zygote development after fertilization. Centrioles in zygotes are definitely derived from the male gamete, irrespective of the sexual reproduction pattern. Female centrioles in zygotes are selectively broken down within 1–2 h after fertilization. The remaining male centrioles play a crucial role as a part of the centrosome for microtubule organization, mitosis, determination of the cytokinetic plane and cytokinesis, as well as for maintaining multicellularity and regular morphogenesis in brown algae.     

Dynamics of Nuclear DNA Quantities during Zygote Development in Barley

Quantities of DNA were estimated in the nuclei of mechanically isolated egg and zygote protoplasts in two cultivars of barley using 4[prime],6-diamidino-2-phenylindole staining and microfluorometry. Unlike many previous studies on DNA amounts within the sex cells of flowering plants, we obtained consistent and unambiguous results indicating that the egg and sperm nuclei are at the 1C DNA level (basic haploid amount) at the time of karyogamy. Karyogamy was initiated within 60 min postpollination, and the male chromatin became completely integrated into the egg nucleus within 6 to 7 hr postpollination (hpp). Zygotic nuclear DNA levels began to increase at ~9 to 12 hpp in cultivar Alexis and at 12 to 15 hpp in cultivar Igri. The 4C DNA complement was reached in most zygotes by 22 to 26 hpp in cultivar Alexis and by 23 to 29 hpp in cultivar Igri. These data are fundamental to a better understanding of fertilization and zygote maturation in flowering plants. They are also relevant to studies in which the timing of zygotic DNA replication is of interest, such as ongoing investigations on genetic transformations in barley using the microinjection technique.     

Male germ line development in Arabidopsis. duo pollen mutants reveal gametophytic regulators of generative cell cycle progression

Male germ line development in flowering plants is initiated with the formation of the generative cell that is the progenitor of the two sperm cells. While structural features of the generative cell are well documented, genetic programs required for generative cell cycle progression are unknown. We describe two novel Arabidopsis (Arabidopsis thaliana) mutants, duo pollen1 (duo1) and duo pollen2 (duo2), in which generative cell division is blocked, resulting in the formation of bicellular pollen grains at anthesis. duo1 and duo2 map to different chromosomes and act gametophytically in a male-specific manner. Both duo mutants progress normally through the first haploid division at pollen mitosis I (PMI) but fail at distinct stages of the generative cell cycle. Mutant generative cells in duo1 pollen fail to enter mitosis at G2-M transition, whereas mutant generative cells in duo2 enter PMII but arrest at prometaphase. In wild-type plants, generative and sperm nuclei enter S phase soon after inception, implying that male gametic cells follow a simple S to M cycle. Mutant generative nuclei in duo1 complete DNA synthesis but bypass PMII and enter an endocycle during pollen maturation. However, mutant generative nuclei in duo2 arrest in prometaphase of PMII with a 2C DNA content. Our results identify two essential gametophytic loci required for progression through different phases of the generative cell cycle, providing the first evidence to our knowledge for genetic regulators of male germ line development in flowering plants.     

Unique Pattern of ORC2 and MCM7 Localization During DNA Replication Licensing in the Mouse Zygote

In eukaryotes, DNA synthesis is preceded by licensing of replication origins. We examined the subcellular localization of two licensing proteins, ORC2 and MCM7, in the mouse zygotes and two-cell embryos. In somatic cells ORC2 remains bound to DNA replication origins throughout the cell cycle, while MCM7 is one of the last proteins to bind to the licensing complex. We found that MCM7 but not ORC2 was bound to DNA in metaphase II oocytes and remained associated with the DNA until S-phase. Shortly after fertilization, ORC2 was detectable at the metaphase II spindle poles and then between the separating chromosomes. Neither protein was present in the sperm cell at fertilization. As the sperm head decondensed, MCM7 was bound to DNA, but no ORC2 was seen. By 4 h after fertilization, both pronuclei contained DNA bound ORC2 and MCM7. As expected, during S-phase of the first zygotic cell cycle, MCM7 was released from the DNA, but ORC2 remained bound. During zygotic mitosis, ORC2 again localized first to the spindle poles, then to the area between the separating chromosomes. ORC2 then formed a ring around the developing two-cell nuclei before entering the nucleus. Only soluble MCM7 was present in the G2 pronuclei, but by zygotic metaphase it was bound to DNA, again apparently before ORC2. In G1 of the two-cell stage, both nuclei had salt-resistant ORC2 and MCM7. These data suggest that licensing follows a unique pattern in the early zygote that differs from what has been described for other mammalian cells that have been studied.     

Ca2+ signals coordinate zygotic polarization and cell cycle progression in the brown alga Fucus serratus

Zygotes of the fucoid brown algae provide excellent models for addressing fundamental questions about zygotic symmetry breaking. Although the acquisition of polarity is tightly coordinated with the timing and orientation of the first asymmetric division--with zygotes having to pass through a G1/S-phase checkpoint before the polarization axis can be fixed--the mechanisms behind the interdependence of polarization and cell cycle progression remain unclear. In this study, we combine in vivo Ca2+ imaging, single cell monitoring of S-phase progression and multivariate analysis of high-throughput intracellular Ca2+ buffer loading to demonstrate that Ca2+ signals coordinate polarization and cell cycle progression in the Fucus serratus zygote. Consistent with earlier studies on this organism, and in contrast to animal models, we observe no fast Ca2+ wave following fertilization. Rather, we show distinct slow localized Ca2+ elevations associated with both fertilization and S-phase progression, and we show that both S-phase and zygotic polarization are dependent on pre-S-phase Ca2+ increases. Surprisingly, this Ca2+ requirement cannot be explained by co-dependence on a single G1/S-phase checkpoint, as S phase and zygotic polarization are differentially sensitive to pre-S-phase Ca2+ elevations and can be uncoupled. Furthermore, subsequent cell cycle progression through M phase is independent of localized actin polymerization and zygotic polarization. This absence of a morphogenesis checkpoint, together with the observed Ca2+-dependences of S phase and polarization, show that the regulation of zygotic division in the brown algae differs from that in other eukaryotic model systems, such as yeast and Drosophila.