Characterization of SP1, a stress-responsive,boiling-soluble,homo-oligomeric protein from aspen

In flowering plants, the vegetative nucleus and the two sperm cells are proposed to form a functional assemblage, the male germ unit (MGU). Here, we describe the developmental pathway of MGU assembly in Arabidopsis and report two classes of mutations that affect the integrity and/or the positioning of the MGU in the mature pollen grain. In germ unit malformed (gum) mutants, the vegetative nucleus is positioned adjacent to the pollen grain wall, separate from the two sperm cells, whereas in MGU displaced (mud) mutants, the intact MGU is displaced to the pollen grain wall. mud and gum mutants correspond to male-specific gametophytic mutations that also reduce pollen fitness. Genetic mapping showed that the gum1 and gum2 mutations are genetically linked, possibly allelic, whereas the mud1 and mud2 mutations correspond to two unlinked loci mapping on different chromosomes. The hierarchical relationship between mud and gum mutations was investigated by phenotypic analysis of double mutants. gum1 appeared to act earlier than mud1 and mud2, affecting initial MGU assembly and its stability during pollen maturation. In contrast, mud1 and mud2 mutations appear to act only on MGU positioning during final maturation. From in planta analyses of pollen germination in mud and gum mutants, we conclude that the initial proximity and positioning of MGU components is not required for their entrance into the pollen tube, but the efficiency of MGU translocation is reduced.     

Migration of sperm cells during pollen tube elongation in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>: behavior during transport,maturation and upon dissociation of male germ unit associations

The promoter sequence of sperm-expressed gene, PzIPT isolated from the S_vn (sperm associated with the vegetative nucleus) of Plumbago zeylanica, was fused to a green fluorescent protein (GFP) reporter sequence and transformed into Arabidopsis thaliana to better visualize the live behavior of angiosperm sperm cells. Angiosperm sperm cells are not independently motile, migrating in a unique cell-within-a-cell configuration within the pollen tube. Sperm cells occur in association with the vegetative nucleus forming a male germ unit (MGU). In Arabidopsis, GFP was expressed equally in both sperm cells and was observed using a spinning disk confocal microscope, which allowed long duration observation of cells without bleaching or visible laser radiation damage. Pollen activation is reflected by conspicuous movement of sperm and pollen cytoplasm. Upon pollen germination, sperm cells enter the forming tube and become oriented, typically with a sperm cytoplasmic projection leading the sperm cells in the MGU, which remains intact throughout normal pollen tube elongation. Maturational changes, including vacuolization, general rounding and entry into G2, were observed during in vitro culture. When MGUs were experimentally disrupted by mild temperature elevation, sperm cells no longer tracked the growth of the tube and separated from the MGU, providing critical direct evidence that the MGU is a functional unit required for sperm transmission.     

Pollen and sperm heteromorphism: convergence across kingdoms?

Sperm competition theory predicts that males should produce many, similar sperm. However, in some species of animals and plants, males exhibit a heteromorphism that results in the production of at least two different types of sperm or pollen grains. In animals, sperm heteromorphism typically corresponds to the production of one fertile morph and one (or more) sterile morph(s), whereas in plants two or more pollen morphs (one of which can be either sterile or fertile) are produced in all flowers but sometimes in different anthers. Heteromorphism has arisen independently several times across phyla and at different phylogenetic levels. Here, we compare and contrast sperm and pollen heteromorphism and discuss the evolutionary hypotheses suggested to explain heteromorphism in these taxa. These hypotheses include facilitation, nutritive contribution, blocking, cheap filler, sperm flushing or killing for animals; outcrossing and precise cross-pollen transfer or bet-hedging strategy for plants; cryptic female choice for both. We conclude that heteromorphism in the two phyla is most likely linked to a general evolutionary response to sexual selection, either to increase one male's sperm or pollen success in competition with other males, or mediate male/female interactions. Therefore, although sperm and pollen are not homologous, we suggest that heteromorphism represents an example of convergence across kingdoms.     

Isolation of the male germ unit: organization and function in tobacco (Nicotiana tabacum L.)

Sperm cells are released from pollen tubes of tobacco as linked cells, associated with the vegetative nucleus in an assemblage known as the male germ unit (MGU). Using light microscopy, the MGU assemblage appears to be ensheathed by cytoplasmic material of the pollen tube, which may stabilize their association. Following their release, the shape of the sperm cells and vegetative nucleus changes from an ellipsoidal to a more spheroidal morphology. When most of the cytoplasmic material is dispersed, a boundary remains around the two sperm cells. Using scanning electron microscopy, the cytoplasmic material surrounding the MGU appears filamentous, sometimes twisted and rope-like. Based on these observations, the function of the MGU of tobacco is discussed. Received: 23 February 1998 / Revision received: 21 May 1998 / Accepted: 1 June 1998     

Studies of the Mature Pollen of Spinacia oleracea after Freeze Substitution and Observed with Confocal Laser Scanning Fluorescence Microscopy

The three-dimensional configuration of the nuclei of the trinucleate pollen grain of Spinacia oleracea L. has been examined by means of confocal laser scanning fluorescence microscopy (CLSM). It shows the presence of a male germ unit (MGU) in which all three nuclei are usually positioned in the periphery of the pollen grain. After freeze fixation and freeze substitution, the ultrastructure is better preserved than with standard chemical fixation. It shows the presence inside the pollen grain of mitochondria, dictyosomes, large starch-containing plastids, endoplasmic reticulum (ER), vacuoles and the MGU. In the sperm cells mitochondria, vesicles, dictyosomes and ER are also found. No microtubules were found in the grain and only very few inside the sperm cells. This is in contrast with earlier published results where fluorescent-labeled antibodies were used.     

Sperm dimorphism in terms of nuclear shape and microtubule accumulation in Cyrtanthus mackenii

Pollen tubes of Cyrtanthus mackenii, a species with bicellular pollen, were cultured in vitro to investigate nuclear phase changes during generative cell division and male germ unit (MGU) formation, using flow cytometric analysis. Results revealed that sperm cells were formed after 12 h of culture. During sperm maturation, the nuclei of sperm cells were not associated with the vegetative nucleus (unassociated sperm cells; Sua) and became longer than those of sperm cells associated with the vegetative nucleus (Svn). These findings indicate that the pair of sperm cells in the C. mackenii MGU is dimorphic in terms of nuclear shape. Dimorphism coincides with anti-α-tubulin antibody immunofluorescence, which was higher in the Sua than in Svn. Following treatment with oryzalin, triggering microtubule depolymerization, differences between nuclear shapes in the two sperm nuclei disappeared, suggesting that microtubule accumulation between sperm cells in the MGU correlates with differences in the nuclear shape.     

The division of the generative nucleus and the formation of callose plugs in pollen tubes of Aechmea fasciata (Bromeliaceae) cultured in vitro

The effect of different external factors on pollen germination and pollen tube growth is well documented for several species. On the other hand the consequences of these factors on the division of the generative nucleus and the formation of callose plugs are less known. In this study we report the effect of medium pH, 2-[N-morpholino]ethanesulfonic acid (MES) buffer, sucrose concentration, partial substitution of sucrose by polyethyleneglycol (PEG) 6000, arginine (Arg), and pollen density on the following parameters: pollen germination, pollen tube length, division of the generative nucleus, and the formation of callose plugs. We also studied the different developmental processes in relation to time. The optimal pH for all parameters tested was 6.7. In particular, the division of the generative nucleus and callose plug deposition were inhibited at lower pH values. MES buffer had a toxic effect; both pollen germination and pollen tube length were lowered. MES buffer also influenced migration of the male germ unit (MGU), the second mitotic division, and the formation of callose plugs. A sucrose concentration of 10% was optimal for pollen germination, pollen tube growth rate and final pollen tube length, as well as for division of the generative nucleus and the production of callose plugs. Partial substitution of sucrose by PEG 6000 had no influence on pollen germination and pollen tube length. However, in these pollen tubes the MGU often did not migrate and no callose plugs were observed. Pollen tube growth was independent of the migration of the MGU and the deposition of callose plugs. In previous experiments Arg proved to be positive for the division of the generative nucleus in pollen tubes cultured in vitro. Here, we found that more pollen tubes had callose plugs and more callose plugs per pollen tube were produced on medium with Arg. After the MGU migrated into the pollen tube (1 h after cultivation), callose plugs were deposited (3 h). After 8 h the first sperm cells were produced. The MGU moved away from the active pollen tube tip until the second pollen mitosis occurred, thereafter the distance from the MGU to the pollen tube tip diminished. Callose plug deposition never started prior to MGU migration into the pollen tube. Pollen tubes without a MGU also lack callose plugs (±30% of the total number of pollen tubes). Furthermore, we found a correlation between the occurrence of sperm cells in pollen tubes and the synthesis of callose plugs.     

Ultrastructural and DNA Epifluorescence Observations of the Sperm Cells of Rhododendron-- with Emphasis on Biparental Plastid Inheritance

The mature pollen grains of Rhododendron mucronulatum Turcz. conform to the 2-celled type. Sperm cells differentiated within the pollen tube about 24 hours after germination in vitro and paired together, one of which being linked with the vegetative nucleus, forming a male germ unit (MGU). Abundance of plastids, mitochondria, microtubules and single-membrane-bounded vesicles could be visualized in each sperm cell, however, endoplasmic reticulum and Golgi apparatus were scarce. The electron-dense plastids with normal structure gave ring-like or dumbbell appearance in sections. Mitochondria were smaller and less electron-dense' in contrast to the plastids. DNA epifluorescence technique revealed that the generative and sperm cells contained numerous organelle nuclei (nucleoids). There was no difference in nucleoid number between the two sperm cells in a pollen tube. The results confirmed the possible existance of cytoplasmic inheritance potential of the male gametes of Rhododendron.     

杜鹃精细胞的超微结构及DNA荧光观察——着重阐明质体双亲遗传的细胞学基础

迎红杜鹃 ( Rhododendron mucronulatum Turcz.)的成熟花粉为二细胞型 ,精细胞在花粉管中形成。花粉管中的两个精细胞及与营养核之间互相联结 ,形成雄性生殖单位。两个精细胞的细胞质中均含有丰富的细胞器 ,包括质体、线粒体、小泡及微管 ,内质网和高尔基体稀少。具正常结构的精细胞质体在切面上多呈环形或哑铃形 ,内膜不发达 ,基质电子密度高。线粒体为球形或棒状 ,基质电子密度较低。 DNA特异性荧光染色显示 ,生殖细胞及精细胞中均含有大量类核 ( nucleoid) ,两个精细胞中的类核数量无明显差异。结果证明了杜鹃精细胞中存在大量具 DNA的可遗传细胞器 ,为杜鹃属植物的双亲细胞质遗传方式提供了细胞学证据。     

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.     

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。     

Interspecific incompatibility in Populus: inhibition of tube growth and behaviour of the male germ unit inP. deltoides×P. alba cross

Summary In order to better understand the cellular events controlling interspecific incompatibility in the genus Populus, the incompatible cross betweenP. deltoides andP. alba has been investigated both at the light and electron microscopic levels. Stained in decolourized aniline blue and observed by epifluorescence microscopy, most incompatible pollen grains are seen to germinate at the stigma surface. Numerous incompatible pollen tubes reach the base of the style where they are arrested 19 h after pollination. Ultrastructural observations on in vivo growing incompatible pollen tubes confirm these data. Very few cytoplasmic modifications are seen within living pollen tubes reaching the lower end of the style or within arrested ones, except the presence of polymorphic plastids. In this predominantly tricellular system, the male germ unit (MGU) is apparently initiated at pollen maturity as an association between the vegetative nucleus and sperm cells. It is maintained during pollen tube growth within the style and persists within arrested incompatible pollen tubes. The unique observation of an association between a dividing generative cell at metaphase and the vegetative nucleus is also reported. Arrested pollen tubes are characterized by apical deformations and accumulation of callose within their thickened cell walls. These cytological data provide additional information on the cellular events associated with interspecific incompatibility in Populus.Abbreviations DAPI 4,6-diamino-2-phenylindole - FCR fluorochromatic reaction - MGU male germ unit     

Ultrastructure of sperm cells and the male germ unit in pollen tubes ofNicotiana tabacum

Summary The structure of sperm cells and their association with the vegetative nucleus in pollen tubes ofNicotiana tabacum grown in styles were observed with the electron microscope, demonstrating the existence of a male germ unit. The two sperm cells are arranged in tandem and are closely associated with the vegetative nucleus, which always takes the lead. The leading sperm cell (SC 1) has a long and narrow cytoplasmic projection which lies within the enclaves of the much lobed vegetative nucleus, thus forming a physical association. The trailing sperm cell (SC 2) and the SC 1 are not only joined by a common transverse cell wall but also are surrounded by a periplasm bounded by the plasma membrane of the sperm cells and that of the vegetative cell, thus forming a structural connection. The sperm cells are elongated, with cytoplasmic projections at the anterior end of the SC 1 and at both ends of the SC 2. The cytoplasm of both sperm cells includes mitochondria, endoplasmic reticulum, dictyosomes, ribosomes, small vacuoles and axially oriented microtubules. No plastids were observed.Abbreviations DAPI 4,6-diamino-2-phenylindole - MGU male germ unit - MT microtubule - SC 1 the leading sperm cell physically associated with the vegetative nucleus - SC 2 the trailing sperm cell     

The evolution of pollen heteromorphism inViola: A phylogenetic approach

Pollen heteromorphism, defined here as the production within all flowers of a plant of several pollen morphs differing in aperture number, is common in angiosperms. We have focused on the evolution of pollen heteromorphism in the genusViola, in which about 1/3 of the species are pollen-heteromorphic. We have studied the distribution of pollen heteromorphism in the genusViola using a molecular phylogeny based on ITS sequence data. We show that pollen heteromorphism has evolved independently at least six times inViola. A comparative analysis shows that the occurrence of pollen heteromorphism is correlated with sporophytic polyploidy in all sections of the genus apart from sectionMelanium. This section differs from all other sections on several aspects such as flower morphology, absence of cleistogamous flowers, and a high proportion of heteromorphic species. We discuss the possible adaptiveness of pollen heteromorphism in this section.     

IS THE PRODUCTION OF MULTIPLE SPERM TYPES ADAPTIVE?

Males of many species concurrently produce more than one sperm type, now called sperm heteromorphism. In the Drosophila obscura group, all species examined to date produce multiple sperm types that differ in sperm length. Short sperm types in at least three obscura group species do not participate in fertilization, leading to questions regarding the adaptive value of sperm heteromorphism. The common and pervasive inheritance of this trait in the obscura group, however, may indicate that sperm heteromorphism is phylogenetically constrained and therefore does not reflect an adaptive response to selection pressures. I measured interspecific variation in sperm length and determined the number of sperm types produced in 10 obscura group species. I subsequently tested if interspecific variation in sperm length is significantly associated with phylogeny by using an autoregressive comparative method. All obscura group species examined produce two visually distinct sperm lengths, short and long. Phylogenetic autoregression analyses indicated that 22% of the interspecific variation in long sperm is related to phylogeny, whereas short sperm are not significantly correlated with phylogeny. These results suggest different selection pressures on the two sperm length types; long sperm have evolved in response to fertilization demands and short sperm have been decoupled from these requirements.     

Gametophytic vs. sporophytic control of pollen aperture number: A generational conflict

In flowering plants, the haploid phase is reduced to the pollen grain and embryo sac. These reproductive tissues (gametophytes) are actually distinct individuals that have a different genome from the plant (sporophyte), and are more or less independent. The morphology of pollen grains, particularly the openings permitting pollen tube germination (apertures), is crucial for determining the outcome of pollen competition. Many species of flowering plants simultaneously produce pollen grains with different aperture numbers in a single individual (heteromorphism). In this paper, we show that the heteromorphic pollen aperture pattern depends on the genetic control of pollen morphogenesis. This points out a conflict of interest between genes expressed in the sporophyte and genes expressed in the gametophyte. More generally, such a conflict should exist whenever heteromorphism is an ESS resulting from a bet-hedging strategy. For pollen aperture, heteromorphism has been observed in about 40% of angiosperm species, suggesting that conflicting situations are the rule. In this context, the sporo-gametophytic conflict could be one of the factors that led to the reduction of the haploid phase in plants.     

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     

被子植物助细胞的发育和功能

助细胞是被子植物雌配子体的组成细胞之一,是大多数被子植物完成受精作用的关键环节之一。在受精过程中,助细胞吸引花粉管向雌配子体生长,并接受花粉管长入细胞程序死亡助细胞中。接下来的花粉管停止生长和花粉管顶端破裂释放出2个精细胞的过程可能也依赖于助细胞。另外,雄性生殖单位的解体、提供精细胞的运动轨道和启动精细胞合成DNA的生物学事件也可能与助细胞有关。助细胞的形态结构已研究得比较清楚,但有关助细胞的发育机理和它在受精过程中的作用则仍不明确。近年来对助细胞的研究又取得了一些新结果,尤其是一些分子生物学的研究结果为揭示助细胞的功能提供了重要线索。该文总结了这方面的研究成果,并对助细胞的生殖功能进行了分析。     

Evolution of intra‐ejaculate sperm interactions: do sperm cooperate?

Sperm are often considered to be individuals, in part because of their unique genetic identities produced as a result of synapsis during meiosis, and in part due to their unique ecology, being ejected away from the soma to continue their existence in a foreign environment. Selection at the level of individual sperm has been suggested to explain the evolution of two enigmatic sperm phenotypes: sperm heteromorphism, where more than one type of sperm is produced by a male, and sperm conjugation, where multiple sperm join together for motility and transport through the female reproductive tract before dissociation prior to fertilization. In sperm heteromorphic species, only one of the sperm morphs typically participates in fertilization, with the non‐fertilizing “parasperm” being interpreted as reproductive altruists. Likewise, in species with sperm conjugation, high levels of sperm mortality have been suggested to be required for conjugate break‐up and this has been considered evidence of kin‐selected altruism. However, it is unclear if sperm possess the heritable variation in fitness (i.e. are individuals) required for the evolution of cooperation. We investigate the question of sperm individuality by focusing on how sperm morphology is determined and how sperm conjugates are formed. Concentrating on sperm conjugation, we discuss functional hypotheses for the evolutionary maintenance of this remarkable trait. Additionally, we speculate on the potential origins of sperm heteromorphism and conjugation, and explore the diversification and losses of these traits once they have arisen in a lineage. We find current evidence insufficient to support the concept of sperm control over their form or function. Thus, without additional evidence of haploid selection (i.e. sperm phenotypes that reflect their haploid genome and result in heritable differences in fitness), sperm heteromorphism and conjugation should be interpreted not as cooperation but rather as traits selected at the level of the male, much like other ejaculatory traits such as accessory gland proteins and ejaculate size.