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     

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.     

Mechanisms of maternal inheritance of plastids and mitochondria: Developmental and ultrastructural evidence

Summary A number of maternally inherited characters are now known to be associated with mitochondria or chloroplasts, which contain small genomes segregating separately from that of the nucleus. The reason often given for maternal inheritance of plastid-associated characters in plants is the absence of plastids in the generative cell of pollen following an unequal mitosis (Vaughn, 1980). However, fine ultrastructural studies have not established “exclusion” as the sole mechanism for maternal inheritance; in many cases, other mechanisms may be operating. Three lines of evidence concerning the mechanism of maternal inheritance will be discussed: First, while it is true that thorough fine ultrastructural studies have failed to find plastids in generative cells of many seed plants (Cass and Karas, 1975), similar studies in some seed plants have found plastids or structures taken to be plastids in generative cells, and a few studies using serial section electron microscopy to re-examine some plants in the first group have found plastids in generative cells and even in the sperm. Also, the exclusion model fails to account at all for maternal inheritance of mitochondria, which are found nearly universally in the generative cells and sperm which have been studied ultrastructurally. Second, maternal inheritance of plastid characters is seen in many lower plants and algae, despite the presence of plastids and mitochondria in the male gametes and their reported deposition in the zygote. Third, there is evidence for an alternative or additional mechanism which may occur in many plants: mitochondria and plastids in male gametes may be altered during development or syngamy so that, although not excluded, they are genetically and perhaps functionally debilitated, which would result in maternal inheritance. This evidence derives both from ultrastructural studies of pollen and fertilization, and from genetic and developmental analysis of algal zygotes and of embryos derived from pollen tissue culture. This mechanism is logically attractive in that it allows for the observed continuum of variation from strict uniparental inheritance in a number of plants, which cannot be explained by the “all-or-nothing” exclusion hypothesis. Indeed, it may be appropriate to think of both mechanisms as part of a continuum ranging from destruction within the zygote, to exclusion during syngamy, to pre-fertilization debilitation, to absence from male gametes and generative cells (Russell and Cass, 1981).     

Arabidopsis CDKA;1, a cdc2 homologue, controls proliferation of generative cells in male gametogenesis

The protein kinase cdc2 is conserved throughout eukaryotes and acts as a key regulator of the cell cycle. In plants, A-type cyclin-dependent kinase (CDKA), a homologue of cdc2, has a role throughout the cell cycle. Here we show that a loss-of-function mutation in CDKA;1, encoding the only Arabidopsis CDKA, results in lethality of the male gametophyte. Heterozygous plants produced mature siliques containing about 50% aborted seeds, and segregation distortion was observed in paternal inheritance. Microspores normally undergo an asymmetric cell division, pollen mitosis I (PMI), to produce bicellular pollen grains. The larger vegetative cell does not divide, but the smaller generative cell undergoes mitosis, PMII, to form the two sperm cells, thereby generating tricellular pollen grains. The cdka-1 mutant, however, produces mature bicellular pollen grains, consisting of a single sperm-like cell and a vegetative cell, due to failure of PMII. The mutant sperm-like cell is fertile, and preferentially fuses with the egg cell to initiate embryogenesis. As the central cell nucleus remains unfertilized, however, double fertilization does not occur. In heterozygous plants, the embryo is arrested at the globular stage, most likely because of loss of endosperm development, whereas it is arrested at the one- or two-cell stage in presumptive homozygous plants. Thus, CDKA;1 is essential for cell division of the generative cell in male gametogenesis.     

Kinetics of double fertilization in Torenia fournieri based on direct observations of the naked embryo sac

Torenia fournieri Lind. has a naked embryo sac that protrudes from the micropyle. The precise time course of the entire process of double fertilization and the kinetics of fertilization events were determined in this species by the following methods: (i) without squashing, pollen tubes on the torn stylar canal were observed by fluorescence microscopy after staining with both 4′,6-diamidino-2-phenylindole (DAPI) and aniline blue; and (ii) large numbers of living embryo sacs were observed directly by differential interference microscopy before and after fertilization. The pollen began to germinate 5 min after pollination and extruded pollen tubes which elongated at a constant rate of 2.3 mm · h⁻¹. At 4.0 h after pollination, the mitotic index of the generative cell within the pollen tube reached 88% and the two sperm cells were formed. Pollen tubes began to arrive at ovules 8.9 h after pollination and directly entered one of two synergids in the naked embryo sac. The time required for transport of sperm cells in the degenerated synergid was estimated statistically to be 1.9 ± 1.8 min for transport of the first cell and 7.4 ± 1.6 min for the second. In the nucleus of the fertilized egg cell, the male nucleolus began to emerge 10 h after pollination and the female nucleolus often decreased in size. The two nucleoli fused together prior to elongation of the zygote, which began 28 h after pollination. In the central cell, the secondary nucleus migrated to a region adjacent to the egg apparatus after pollination but prior to the arrival of the pollen tube. The primary endosperm nucleus rapidly returned to the inner region after fertilization. Prior to embryogenesis, the first division of the primary endosperm began about 15 h after pollination, at a defined site, to form the chalazal haustorium. Received: 24 October 1996 / Accepted: 13 March 1997     

Flow Cytometric Determination of Relative Nuclear DNA Contents in Bicellulate and Tricellulate Pollen

Nuclear DNA content in mature pollen was measured with a flowcytometer Pollen of Lilium longiflorum, Dendranthema grandiflora(syn Chrysanthemum monfolium) and Zea mays was chopped and stainedwith the DNA fluorochrome DAPI DNA levels, expressed as arbitraryC values, were compared with those of nuclei isolated from leafor root material of the same plants In mature tricellulate pollen the generative cell is dividedafter second pollen mitosis into two sperm cells Tricellulatepollen from maize and chrysanthemum gave rise to one large 1Cpeak and, only in the case of chrysanthemum, a much smallerone at the 2C level These results suggest that the haploid nucleiof the vegetative as well as both sperm cells in tricellulatepollen are arrested in the G₁ stage of nuclear division Thesmall 2C peak in the case of chrysanthemum probably arose froma fraction of pollen with the sporophytic chromosome number(2n pollen) In contrast to this, mature bicellulate lily pollengave rise to two identical peaks at the 1C and the 2C levelFrom this result it was concluded that in bicellulate pollen,the 1C peak is caused by the signal of the haploid vegetativenucleus arrested in the G₁ stage of nuclear division, whereasthe 2C peak originates from the haploid generative nucleus whichhas already undergone DNA synthesis and is arrested in G₂ Lilium longiflorumThunb, lily, Dendranthema grandiflora Tzelev (syn Chrysanthemum morifolium Ramat ), chrysanthemum, Zea maysL, maize, male gametophytic cells, vegetative cells, generative cells, sperm cells, unreduced pollen, sporophytic cells, relative nuclear DNA contents, replication stage     

YAO is a nucleolar WD40-repeat protein critical for embryogenesis and gametogenesis in Arabidopsis

Background  

In flowering plants, gametogenesis generates multicellular male and female gametophytes. In the model system Arabidopsis, the male gametophyte or pollen grain contains two sperm cells and a vegetative cell. The female gametophyte or embryo sac contains seven cells, namely one egg, two synergids, one central cell and three antipodal cells. Double fertilization of the central cell and egg produces respectively a triploid endosperm and a diploid zygote that develops further into an embryo. The genetic control of the early embryo patterning, especially the initiation of the first zygotic division and the positioning of the cell plate, is largely unknown.     

烟草精细胞两个群体的分离

高等植物的倾向受精是一个非常吸引人的研究课题,目前对其机理还不清楚。要想探索高等植物倾向受精现象,前提之一是要分离出一定数量的两个精细胞群体作为分子生物学研究方法的材料。以前的研究表明, 烟草(Nicotiana tabacum L.)花粉管中的两个精细胞体积差异明显。这种异型性的精细胞可能与倾向受精有关。烟草是二胞型花粉,生殖细胞只在体内生长的花粉管中才分裂形成两个精细胞。用体内/体外技术培养出花粉管后,爆破花粉管即可释放出花粉管内含物,其中包括两个精细胞。用微量酶液可使两个精细胞分开。然后用显微操作器可挑选出两个大小不同、数量上千的精细胞群体。这种单一纯化的精细胞群体为用分子生物学方法区分两个精细胞的DNA和蛋白质差异打下基础。本研究是高等植物的第二例、二胞花粉植物中的第一例分离两个特定精细胞群体的尝试,为构建烟草两个精细胞的cDNA文库创造了条件。     

烟草精细胞两个群体的分离

高等植物的倾向受精是一个非常吸引人的研究课题,目前对其机理还不清楚.要想探索高等植物倾向受精现象,前提之一是要分离出一定数量的两个精细胞群体作为分子生物学研究方法的材料.以前的研究表明,烟草(Nicotiana tabacum L.)花粉管中的两个精细胞体积差异明显.这种异型性的精细胞可能与倾向受精有关.烟草是二胞型花粉,生殖细胞只在体内生长的花粉管中才分裂形成两个精细胞.用体内/体外技术培养出花粉管后,爆破花粉管即可释放出花粉管内含物,其中包括两个精细胞.用微量酶液可使两个精细胞分开.然后用显微操作器可挑选出两个大小不同、数量上千的精细胞群体.这种单一纯化的精细胞群体为用分子生物学方法区分两个精细胞的DNA和蛋白质差异打下基础.本研究是高等植物的第二例、二胞花粉植物中的第一例分离两个特定精细胞群体的尝试,为构建烟草两个精细胞的cDNA文库创造了条件.     

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.     

绿色荧光蛋白基因结合鼠Talin基因蛋白标记转基因水稻活体生殖细胞及精细胞的微丝骨架

利用绿色荧光蛋白(GFP)基因结合鼠Talin基因表达技术及水稻(Oryza sativa L.)转基因技术,筛选出表达稳定和具等位基因型的第三代转基因水稻.在其活体花粉的4个发育阶段(Ⅰ.小孢子晚期;Ⅱ.二细胞早期;Ⅲ.二细胞晚期;Ⅳ.三细胞阶段),观察了细胞内微丝骨架的分布和结构形态的变化.发现在这4个花粉发育阶段,花粉内的营养核、生殖核、生殖细胞和精细胞都在不同的发育阶段出现位移.而这些位移与微丝骨架的结构变化和运动有密切关系.在胞质中央的微丝网络以及细胞周质的网络不断变化和互动,导致营养核、生殖核或生殖细胞和精细胞的定向位移.在活体生殖细胞和精细胞内,存有一股与细胞纵轴平行排列的微丝骨架.这些微丝骨架对生殖细胞及精细胞可以提供移动的动力,这对生殖细胞或精细胞在花管内以及胚囊内的运动(包括独自游动)提供了依据.     

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。     

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。     

Cytoplasmic connection of sperm cells to the pollen vegetative cell nucleus: potential roles of the male germ unit revisited

The male germ cells of angiosperm plants are neither free-living nor flagellated and therefore are dependent on the unique structure of the pollen grain for fertilization. During angiosperm male gametogenesis, an asymmetric mitotic division produces the generative cell, which is completely enclosed within the cytoplasm of the larger pollen grain vegetative cell. Mitotic division of the generative cell generates two sperm cells that remain connected by a common extracellular matrix with potential intercellular connections. In addition, one sperm cell has a cytoplasmic projection in contact with the vegetative cell nucleus. The shared extracellular matrix of the two sperm cells and the physical association of one sperm cell to the vegetative cell nucleus forms a linkage of all the genetic material in the pollen grain, termed the male germ unit. Found in species representing both the monocot and eudicot lineages, the cytoplasmic projection is formed by vesicle formation and microtubule elongation shortly after the formation of the generative cell and tethers the male germ unit until just prior to fertilization. The cytoplasmic projection plays a structural role in linking the male germ unit, but potentially plays other important roles. Recently, it has been speculated that the cytoplasmic projection and the male germ unit may facilitate communication between the somatic vegetative cell nucleus and the germinal sperm cells, via RNA and/or protein transport. This review focuses on the nature of the sperm cell cytoplasmic projection and the potential communicative function of the male germ unit.     

Double fertilization in maize: the two male gametes from a pollen grain have the ability to fuse with egg cells

In flowering plants, two male gametes from a single pollen grain fuse with two female gametes, the egg and central cells, to form the embryo and endosperm, respectively. The question then arises whether the two male gametes fuse randomly with the egg and central cells. We investigated this question using two nearly isogenic maize lines with supernumerary B chromosomes (TB10L18) or without (r-tester). B chromosomes regularly undergo non-disjunction at the second pollen mitosis, producing one sperm cell with zero B chromosomes and one with two. We first confirmed earlier studies showing an excess of transmission of the B chromosomes to the embryo rather than to the endosperm. We then tested the possibility of a directed fertilization. For TB10L18 pollen, we could demonstrate the existence of a size dimorphism between the two sperm cells, correlated to the content in B chromosomes, as detected by fluorescence in situ hybridization (FISH). However, no directed fusion of B chromosome containing sperm to egg cells could be detected when using in vitro fertilization. The absence of directed fusion in vitro could also be demonstrated for control lines. We conclude that both male gametes have the capacity to fuse with the egg cell in maize, although sexual reproduction results in a preferential transmission of supernumerary B chromosomes.     

Differentiation of generative and vegetative cells in angiosperm pollen

 Cellular differentiation of a generative and a vegetative cell is an important event during microspore and pollen development and is requisite for double fertilization in angiosperms. The generative cell produces two sperm cells, or male gametes, whereas the vegetative cell produces an elongated pollen tube, a gametophytic cell, to deliver the male gametes to the embryo sac. For typical differentiation of the gametic and gametophytic cells, cell polarity, including nuclear positioning, must be established prior to microspore mitosis and be maintained during mitosis. Microtubules are closely involved in the process of asymmetric cell division. On the other hand, alteration of the chromatin composition seems to be responsible for the differential gene expression between the generative and vegetative cells. Cytoplasmic regulatory molecules, which affect chromatin configuration, are postulated to be unequally distributed to the two cells at the asymmetric cell division. Thus, typical differentiation of the cells is accomplished by a cellular mechanism and a molecular mechanism, which might be independent of each other. These results are discussed in relation to one model that accounts for the different fates of generative and vegetative cells during sexual plant reproduction. Received: 3 September 1996 / Revision accepted: 23 September 1996     

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。     

Electrofusion-mediated transmission of cytoplasmic organelles through the in vitro fertilization process,fusion of sperm cells with synergids and central cells,and cell reconstitution in maize

Summary Fusion products were created by the electrofusion of single sperm cells with single synergids and central cells. The synergid was also fused with the sperm cell, occasionally in the presence of adhering second synergids, egg cells, and central cells. Single egg cells were fused with single sperm cells in the presence of adhering synergids and the central cell. Cytoplasmic organelles were transmitted through the fertilization process by electrofusion using cytoplasts of maize mesophyll cells. Cell reconstitution was achieved by fusion of one or two sperm cells with single enucleated protoplasts, thus creating a haploid or a diploid cell.     

Microgametogenesis in Plumbago zeylanica (Plumbaginaceae). 2. Quantitative cell and organelle dynamics of the male reproductive cell lineage

Quantitative cell and organelle dynamics of the male gamete-producing lineage of Plumbago zeylanica were examined using serial transmission electron microscopic reconstruction at five stages of development from generative cell inception to sperm cell maturity. The founder population of generative cell organelles includes an average of 3.88 plastids, 54.9 mitochondria, and 3.7 vacuoles. During development the volume of the pollen grain increases from 6,200 μm³ in early microspores to 115,000 μm³ at anthesis, cell volume of the male germ lineage decreases more than 67% from 362.3 μm³ to 118.4 μm³. By the time the generative cell separates from the intine, plastid numbers increase by >600%, mitochondria by 250%, and vesicles by 43 times. A cellular projection elongates toward and establishes an association with the vegetative nucleus; this leading edge contains plastids and numerous mitochondria. When the generative cell completes its separation from the intine, organellar polarity is reversed and plastids migrate to the opposite pole of the cell. Cytoplasmic microtubules are common in association with cellular organelles. Plastids accumulate at the distal end of the cell as a linked mass, apparently adhered by lateral electron dense regions. Before division of the highly polarized generative cell, plastids decrease in number by 16%, whereas mitochondria increase by ∼90% and vacuoles increase by ∼140% from the prior stage. After mitosis, the resultant sperm cells differ in size and organelle content. The sperm cell associated with the vegetative nucleus (S_vn) contains 62.7% of the cytoplasm volume, 87% of the mitochondria, 280.4 vesicles (79% of those in the generative cell), and 0.6% of the plastids. At maturity, the S_vn mitochondria increase by 31% and the cell contains an average of 0.4 plastids, 158.9 vesicles, and 0.36 microbodies. The mature unassociated sperm (S_ua) contains 39.8 mitochondria (up 3.3%), 24.3 plastids (down 31%), 91.1 vesicles (up 54.9%), and 3.18 microbodies. The small number of organelles initially in the generative cell, followed by their rapid multiplication in a shrinking cytoplasm suggests a highly competitive cytoplasmic environment that would tend to eliminate residual organellar heterogeneity. Cell and cytoplasmic volumes vary as a consequence of fluctuations in the number and size of large vesicles or vacuoles, as well as loss of cytoplasmic volume by (1) formation of “false cells” involving amitotic cytokinesis, (2) “pinching off” of cytoplasm, and (3) dehydration of pollen contents prior to anthesis.