Histone H3 variants in male gametic cells of lily and H3 methylation in mature pollen

Histones are vital structural proteins of chromatin that influence its dynamics and function. The tissue-specific expression of histone variants has been shown to regulate the expression of specific genes and genomic stability in animal systems. Here we report on the characterization of five histone H3 variants expressed in Lilium generative cell. The gcH3 and leH3 variants show unique sequence diversity by lacking a conserved lysine residue at position 9 (H3K9). The gH3 shares conserved structural features with centromeric H3 of Arabidopsis. The gH3 variant gene is strongly expressed in generative cells and gH3 histone is incorporated in to generative cell chromatin. The lysine residue of H3 at position 4 (H3K4) is highly methylated in the nuclei of generative cells of mature pollen, while methylation of H3K4 is low in vegetative cell nuclei. Taken together, these results suggest that male gametic cells of Lilium have unique chromatin state and histone H3 variants and their methylation might be involved in gene regulation of male gametic cells.Accession numbers for the sequence data The sequences reported in this paper have been deposited in the DDBJ database gcH3 GC1174 (accession no. AB195644), gH3 GC1008 (accession no. AB195646), leH3 GC1126 (accession no. AB195648), soH3-1 GC0075 (accession no. AB195650), soH3-2 GC1661 (accession no. AB195652), genomic sequence of gcH3 (accession no. AB195645), genomic sequence of gH3 (accession no. AB195647), genomic sequence of leH3 (accession no. AB195649), genomic sequence of soH3-2 (accession no. AB195651), genomic sequence of soH3-2 (accession no. AB195653).     

Establishment of the male germline and sperm cell movement during pollen germination and tube growth in maize

Two sperm cells are required to achieve double fertilization in flowering plants (angiosperms). In contrast to animals and lower plants such as mosses and ferns, sperm cells of flowering plants (angiosperms) are immobile and are transported to the female gametes (egg and central cell) via the pollen tube. The two sperm cells arise from the generative pollen cell either within the pollen grain or after germination inside the pollen tube. While pollen tube growth and sperm behavior has been intensively investigated in model plant species such as tobacco and lily, little is know about sperm dynamics and behavior during pollen germination, tube growth and sperm release in grasses. In the March issue of Journal of Experimental Botany, we have reported about the sporophytic and gametophytic control of pollen tube germination, growth and guidance in maize.1 Five progamic phases were distinguished involving various prezygotic crossing barriers before sperm cell delivery inside the female gametophyte takes place. Using live cell imaging and a generative cell-specific promoter driving α-tubulin-YFP expression in the male germline, we report here the formation of the male germline inside the pollen grain and the sperm behaviour during pollen germination and their movement dynamics during tube growth in maize.Key words: male gametophyte, generative cell, sperm, pollen tube, tubulin, fertilization, maize     

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.     

Analysis of sticky generative cell mutants reveals that suppression of callose deposition in the generative cell is necessary for generative cell internalization and differentiation in Arabidopsis

In flowering plants, double fertilization between male and female gametophytes, which are separated by distance, largely depends on the unique pattern of the male gametophyte (pollen): two non-motile sperm cells suspended within a tube-producing vegetative cell. A morphological screen to elucidate the genetic control governing the strategic patterning of pollen has led to the isolation of a sticky generative cell (sgc) mutant that dehisces abnormal pollen with the generative cell immobilized at the pollen wall. Analyses revealed that the sgc mutation is specifically detrimental to pollen development, causing ectopic callose deposition that impedes the timely internalization and differentiation of the generative cell. We found that the SGC gene encodes the highly conserved domain of unknown function 707 (DUF707) gene that is broadly expressed but is germline specific during pollen development. Additionally, transgenic plants co-expressing fluorescently fused SGC protein and known organelle markers showed that SGC localizes in the endoplasmic reticulum, Golgi apparatus and vacuoles in pollen. A yeast two-hybrid screen with an SGC bait identified a thaumatin-like protein that we named GCTLP1, some homologs of which bind and/or digest β-1,3-glucans, the main constituent of callose. GCTLP1 is expressed in a germline-specific manner and colocalizes with SGC during pollen development, indicating that GCTLP1 is a putative SGC interactor. Collectively, our results show that SGC suppresses callose deposition in the nascent generative cell, thereby allowing the generative cell to fully internalize into the vegetative cell and correctly differentiate as the germline progenitor, with the potential involvement of the GCTLP1 protein, during pollen development in Arabidopsis.     

The influence of animal sex hormones on the induction of flowering in Arabidopsis thaliana: comparison with the effect of 24-epibrassinolide

The influence of selected steroids on the in vitro generative development of Arabidopsis thalianawas investigated. The activity of the animal steroids androsterone, androstenedione, progesterone, estrone, estriol, and 17-estradiol was compared to 24-epibrassinolide, a member of the regulatory family of brassinosteroids. A. thaliana plants were cultured in vitro in media containing these steroids. The stimulatory effect of the tested substances was evaluated by measurement of the percentage of generative plants versus vegetative plants in the experimental group. It was established that androstenedione, the main testosterone precursor, and androsterone, a typical male hormone, were more effective in stimulating flowering in A. thaliana than the female hormones, estrogens and progesterone. Androsterone at a concentration of 0.1 M increased the percentage of generative plants up to 96% (control 41%). Estrogens at the same concentration decreased the number of generative plants and 24-epibrassinolide did not stimulate A. thalianagenerative development.     

被子植物生殖细胞与精细胞的分离方法

开花植物精细胞的发育经历一个独特的后减数分裂过程,在此过程中每个花粉母细胞减数分裂的产物——小孢子经不对称有丝分裂产生1个大的营养细胞和1个小的生殖细胞,随后生殖细胞经过正常的有丝分裂产生2个精细胞。近几年,随着高通量组学技术的不断完善,利用组学技术比较分析生殖细胞和精细胞的分子特征、揭示决定精细胞命运与功能以及受精识别的重要分子已成为植物生殖生物学备受关注的课题。开展此项研究的关键是建立能获得大量高纯度的生殖细胞与精细胞分离纯化技术。该文综述了被子植物生殖细胞和精细胞分离方法的主要研究进展,分析了关键方法的特点和要点以及不同方法之间的差异和共性,以期为相关领域的研究人员提供借鉴。     

The plasma membrane and generative cell organization in pollen of the mimosoid legume,Acacia retinodes

Summary Cytological changes associated with the final maturation, and dehiscence of the 16-grain compound pollen (polyads) have been followed in anthers at female and male phase of flowering. InAcacia retinodes, the transition from female to male phase takes approximately 24 h. The spherical generative cell at female phase is connected with the vegetative cell plasma membrane by a junction zone. This is sited adjacent to a germinal aperture, comprising wall ingrowths and membrane labyrinths. By male phase, the generative cell has elongated into a spindle-shape, and its surface is characteristically scalloped. The membrane labyrinths, especially those at the apertures, now contain masses of coated vesicles, implicated in the transport and secretion of proteins. Two-dimensional projections indicate that the generative cell and vegetative nucleus are closely associated forming a male germ unit.     

An original mutation in soybean (Glycine max (L.) Merrill) involving degeneration of the generative cell and causing male sterility.

A spontaneous mutation causing male sterility has been detected in line BR97-17739 from the soybean breeding program conducted by Embrapa-National Soybean Research Center. Meiotic division and male gametophyte development were analyzed in 10 male-sterile, female-fertile plants. Meiotic process had few irregularities related to chromosome segregation and affected about 2% of tetrads. Despite the high frequency of normal microspores, pollen sterility was total. After callose dissolution, microspores were released into the anther loculle and interphase nucleus was displaced from the center to one side of the cell. Displacement continued throughout normal microspore mitosis (PMI). After telophase, the hemispherical phragmoplast marked the place of cytokinesis. A typical generative cell, adjacent to the plasma membrane, and the vegetative one, containing most of the cytoplasm, were formed. In spite of the well-formed generative cell, pollen mitosis (PMII) failed to occur. The generative cell degenerated and was completely destroyed. The 3:1 segregation for male sterility in this line and its progenies indicate that a single recessive gene controls mutation.     

Immunoelectron microscopy of myosin associated with the generative cells in pollen tubes ofNicotiana tabacum L.

In this study, polyclonal anti-myosin antibodies were used for immunogold labeling of ultrathin sections of pollen tubes ofNicotiana tabacum L. to unravel the ultrastructural localization of myosin associated with the generative cells. Clusters of immunogold particles were consistently found in association with the area of the outer surface of the vegetative cell plasma membrane present around the generative cell. Compared to the generative cell cytoplasm, the nucleoplasm showed higher numbers of gold particles. This is the first direct evidence demonstrating the presence of myosin in the nuclei of the generative cell of flowering plants. The possible implications of these findings are discussed in relation to movement of the generative cell in the pollen tube cytoplasm.     

Male Gametic Cell-specific Histone <Emphasis Type="Italic">gH2A</Emphasis> Gene of <Emphasis Type="Italic">Lilium longiflorum</Emphasis>: Genomic Structure and Promoter Activity in the Generative Cell

A genomic clone containing the gH2A gene, a histone variant specifically expressed in male gametic cells within the pollen of Lilium longiflorum, was isolated. Sequence analysis revealed that the coding region of the gene is interrupted by one intron, as is the case with the somatic type of plant histone H2A genes, suggesting derivation from the same ancestral gene containing one intron. In addition, a 2.8-kbp fragment of the 5′ upstream region of gH2A contained TATA and CAAT boxes, but neither a plant histone-specific regulatory DNA element nor vegetative cell-specific cis-elements were found. A histochemical study of stable transformants demonstrated that the 5′ upstream region of the gene can drive gene expression specifically in the generative cell of pollen; no activity was detectable in the vegetative cell or in other reproductive and vegetative tissues of transgenic Nicotiana tabacum. These results strongly suggest that the generative cell can direct specific gene expression, that this expression may be regulated by a putative male gametic factor, and that the gH2A promoter may therefore serve as a useful male gametic cell fate marker in angiosperms.     

Proteomic analysis reveals the differential histone programs between male germline cells and vegetative cells in Lilium davidii

In flowering plants, male germline fate is determined after asymmetric division of the haploid microspore. Daughter cells have distinct fates: the generative cell (GC) undergoes further mitosis to generate sperm cells (SCs), and the vegetative cell (VC) terminally differentiates. However, our understanding of the mechanisms underlying germline development remains limited. Histone variants and modifications define chromatin states, and contribute to establishing and maintaining cell identities by affecting gene expression. Here, we constructed a lily protein database, then extracted and detailed histone entries into a comprehensive lily histone database. We isolated large amounts of nuclei from VCs, GCs and SCs from lily, and profiled histone variants of all five histone families in all three cell types using proteomics approaches. We revealed 92 identities representing 32 histone variants: six for H1, 11 for H2A, eight for H2B, five for H3 and two for H4. Nine variants, including five H1, two H2B, one H3 and one H4 variant, specifically accumulated in GCs and SCs. We also detected H3 modification patterns in the three cell types. GCs and SCs had almost identical histone profiles and similar H3 modification patterns, which were significantly different from those of VCs. Our study also revealed the presence of multiple isoforms, and differential expression patterns between isoforms of a variant. The results suggest that differential histone programs between the germline and companion VCs may be established following the asymmetric division, and are important for identity establishment and differentiation of the male germline as well as the VC.     

Induced single fertilization in maize

 Bicellular pollen with one vegetative nucleus and one diploid arrested generative cell (”monospermic” pollen) was induced by trifluralin treatment of diploid maize plants at 7–9 days before flowering. The arrested generative cell (seemingly a diploid sperm cell) fused with the central cell of diploid plants and produced shriveled endosperm resembling that of a 2n×4n cross in maize. Dual pollination experiments with a purple embryo marker revealed single fertilization events in which the union of one sperm cell with the egg occurs but there is no union of a second sperm cell with the central cell. Singly fertilized ovules survived at least 4 days. Furthermore, many viable triploid plants were obtained. This technique therefore appears to have the potential for manipulating ploidy level in crops and may become useful in investigating fertilization mechanisms of angiosperms. Received: 1 October 1996 / Revision accepted: 8 January 1997     

ULTRASTRUCTURAL COMPARISION OF POLLEN GRAINS FROM 2n, 3n,AND 4n PLANTS OF EUPHORBIA DULCIS

Pollen development in plants with different ploidy levels of Euphorbia dulcis is similar but some ultrastructural differences do occur. In pollen of diploid plants large aggregations of rough endoplasmic reticulum [RER] are attached to the pollen wall near the young generative cell but such aggregations are not present in other karyotypes. Plastids are detected only in young generative cells of triploid plants. In diploid plants the generative cell becomes spindle-shaped, in triploid and tetraploid plants it remains round during the movement from the pollen wall to the center of the vegetative cell. The intine surrounding the generative cell in 3n plants is thinner than that found in 2n and 4n plants. Pollen grains in tetraploid plants are twice as large as those in diploid plants. Pollen viability is 90% in 2n plants, but only 10% in 4n plants.     

Changes in the content of endogenous auxins in apical buds ofchenopodium rubrum L. Induced with respect to the endogenous rhythm in capacity to flower

The content of endogenous auxins was examined in apical buds ofChenopodium rubrum plants induced by a photoperiodic cycle of 16h darkness and 8h light followed by a dark period of various duration so as to correspond with either maximal or minimal flowering response in the endogenous rhythm in capacity to flower initiated by the photoperiodic treatment. Apical buds of potentially generative plants contained less auxins than apical buds of plants which remained in the vegetative state. Apical buds from plants treated with kinetin (1. 10^-3 M) and therefore remaining in the vegetative state showed an auxin level comparable to that of untreated plants exhibiting minimal flowering response irrespective of the duration of the second dark period. Plants cultivated on a sucrose solution (0.6 M) during the second dark period became generative even at the normal minimum of flowering. The auxin content of the apical buds was low, similarly as in untreated plants induced for a period leading to maximal flowering response. On the other hand, apical buds from plants grown on sucrose solution during a dark period leading to the manifestation of maximal flowering response showed a relatively high auxin content comparable to that found in untreated plants which had obtained a more extended induction by three photoperiodic cycles. The results are discussed with respect to the possible role of endogenous auxins in the regulation of the changes in growth correlations occurring in the shoot apex during photoperiodic induction and in the expression of the competence to flower.     

Localization of myosin on sperm-cell-associated membranes of tobacco (Nicotiana tabacum L.)

Summary Actomyosin interactions are reportedly the principal mechanism for the transport of nonmotile sperm cells of flowering plants inside the pollen tube and inside the embryo sac. Myosin has been demonstrated on the generative cell (the predecessor of sperm cells), although it is unclear from previous studies whether myosin is located directly on the plasma membrane of the male germ cells or on the external plasma membrane of the pollen cell that surrounds them. Immunogold scanning electron microscopy was used to localize myosin on isolated tobacco sperm cells, with and without associated membranes. When present, the pollen tube plasma membrane surrounding the sperm cells was labeled by an antimyosin antibody, as were pollen tube cytoplasmic organelles. Negligible labeling was observed directly on the plasma membrane of the sperm cells.