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 male germ unit of Rhododendron: quantitative cytology,three-dimensional reconstruction,isolation and detection using fluorescent probes

Summary The sperm cells of Rhododendron laetum and R. macgregoriae differentiate within the pollen tube about 24 h after germination in vitro. Threedimensional reconstruction shows that the sperm cells are paired together, and both have extensions that link with the tube nucleus, forming a male germ unit. Quantitative analysis shows that the sperm cells in each pair differ significantly in surface area, but not in cell volume nor in numbers of mitochondria or plastids. When isolated from pollen tubes by osmotic shock, the sperm cells became ellipsoidal and surrounded by their own plasma membrane, while a proportion remained in pairs linked by the inner tube plasma membrane. Both generative and sperm cells are visualized in pollen tube preparations by immunofluorescence with anti-tubulin and anti-actin monoclonal antibodies (MAbs) combined with H33258 fluorescence of the nuclei. Video-image processing shows the presence of an axial microtubule cage in the generative cells, and some microtubules are present in the cytoplasmic extensions that clasp the tube nucleus. Following sperm cell division, the extensive phragmoplast between the sperm nuclei is partitioned by the plasma membranes.     

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     

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.     

Male Germ Unit and Sperm Heteromorphism: The Current Status

In angiosperms, two sperms have been recognized as cells linked together by themselves and closely associated with the vegetative nucleus in pollen grain or in pollen tube ;o form so called the “male germ unit (MGU)”In addition to MGU, recent studies have shown the existence in several plants that the two sperm cells in pair may be very different in size, shape, organelle content, and sperm heteromorphism. The concept of the MGU and sperm heteromorphism has appeared in more than 40 reports and has triggered new research concerning the angiosperm fertilization process, In this review, a survey and analysis of the MGU and sperm heteromorphism in literature of last decade are presented and the new experimental approaches are suggested.     

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.     

Actin-endoplasmic reticulum complexes inDrosera

In epidermal cells ofDrosera tentacles that have been preserved for ultrastructural analysis through high pressure freeze fixation and freeze substitution we describe the frequent occurrence of microfilament (MF)-endoplasmic reticulum (ER) complexes. These are found throughout the cytoplasm where they are observed in close association with the plasmalemma (PL), the tonoplast, nuclei, mitochondria, chloroplasts, and microbodies. The MF component of the complexes is identified as actin based on immunogold labelling with actin antibodies. The actin-ER complexes are prominent in the cortical cytoplasm. In this region a network of predominantly tubular ER occupies an intermediary position in which it associates closely with both the PL and the actin MFs. We suggest that the ER, especially those elements adjacent to the PL in the cortical cytoplasm, stabilizes the actin MFs and provides the necessary anchor against which the forces for cytoplasmic streaming are generated.Abbreviations CF chemical fixation - ER endoplasmic reticulum - FS freeze substitution - HPF high pressure freezing - MF microfilaments - MT microtubules - PL plasmalemma     

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.     

CAPSELLA EMBRYOGENESIS: THE SYNERGIDS BEFORE AND AFTER FERTILIZATION

The ultrastructure and composition of the synergids of Capsella bursa-pastoris were studied before and after fertilization. The synergids in the mature embryo sac contain numerous plastids, mitochondria, dictyosomes and masses of ER and associated ribosomes. Each synergid contains a large chalazal vacuole, a nucleus with a single nucleolus and is surrounded by a wall. This wall is thickest at the micropyle end of the cell where it proliferates into the filiform apparatus. At the chalazal end of the cell the wall thins and may be absent for small distances. The pollen tube grows into one of the two synergids through the filiform apparatus and extends one-third the length of the cell before it discharges. Following discharge of the pollen tube, mitochondria and plastids of the tube can be identified in the synergid as can hundreds of 0.5 μ polysaccharide spheres liberated by the tube. The method by which the sperm or sperm nuclei enter the egg or central cell is not known although an apparent rupture was found in the wall of the egg near the tip of the pollen tube. The second synergid changes at the time the pollen tube enters the first synergid. These changes result in the disorganization of the nucleus and loss of the chalazal wall and plasma membrane. Eventually this synergid loses its identity as its cytoplasm merges with that of the central cell.     

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。     

ORCHID EMBRYOLOGY: MEGAGAMETOPHYTE OF EPIDENDRUM SCUTELLA FOLLOWING FERTILIZATION

The megagametophyte of Epidendrum scutella, an orchid, was examined with the electron microscope after the entrance and discharge of the pollen tube. The pollen tube enters the embryo sac by growing through the filiform apparatus of a synergid and discharges through a terminal pore into the degenerating cytoplasm of the synergid. The synergid nucleus appears pushed to one side by the discharge of the pollen tube. What is believed to be the remains of the vegetative nucleus has been found in the degenerate synergid, but no trace of the sperm cytoplasm has been seen. The zygote is approximately the same size as the egg. The ribosomes become grouped into polysomes. Both the egg and the zygote apparently completely lack dictyosomes. The polar nuclei partially fuse before fertilization, but fusion of the sperm nucleus with the polar nuclei does not occur and no endosperm is produced. Polysome formation occurs in the central cell and large amounts of tubular, smooth ER are seen. The antipodals remain following fertilization, undergoing ultrastructural changes similar to the central cell.     

Ultrastructure of the sperms ofPlumbago zeylanica

Summary Male gametes ofPlumbago zeylanica were examined in pollen grains and tubes using light and electron microscopy of chemically and physically fixed tissues, and Nomarski interference microscopy of isolated, living sperm cells. Male gametes are elongate, spindleshaped cells containing a nucleus, mitochondria, ER, ribosomes, vesicles, dictyosomes, probable microfilaments, and a variable number of plastids. In mature pollen grains ofP. zeylanica, the two sperm cells are directly linked; they share a transverse cell wall with plasmodesmata and are enclosed together by the inner vegetative cell plasma membrane. One of these two sperms is also associated with the vegetative nucleus as a consistent feature of pollen grain organization. The basis of this association appears to be a long, narrow projection of the sperm cell (averaging < 1 m wide and about 30 m long) which wraps around the periphery of the vegetative nucleus and occupies embayments of that nucleus. This association is maintained throughout pollen tube growth but becomes less extensive near the completion of tube growth and is severed following tube discharge. The consistent occurrence of the sperm-vegetative nucleus association in pollen grains, tubes and isolated pollen cytoplasm suggests that the two structures may be directly connected, but attempts to visualize this type of connection were unsuccessful. Possibly, the entwining nature and extent of complementary interfaces between vegetative nucleus and sperm may have a role in stabilizing their association. Functionally, the two sperms and vegetative nucleus appear to travel as a linked unit within the pollen tube, possibly increasing the effectiveness of gamete delivery and helping to ensure nearly simultaneous transmission of sperms into the receptive megagametophyte.     

AN ELECTRON MICROSCOPE STUDY OF GERMINATING LYCHNIS ALBA POLLEN

The fine structure of germinating Lychnis alba pollen is described and correlated with some basic tests for chemical composition. The primary storage product in both pollen grain and pollen tube appears to be lipid. Pregermination synthesis of pollen tube wall material appears characteristic in this species, along with the presence of crystalloid structures having approximately 80 A periods. The crystalloid bodies are not found in the tip cytoplasm of the pollen tubes. Limited acid phosphatase activity is found associated with the crystalloid structures as well as within vesiculate structures of the pollen grain. The cytoplasmic structure of both the pollen grains and pollen tubes is characterized by few dictyosomes and plastids and no microtubules, although mitochondria and polyribosomes are abundant. Pectins have not been verified in the pollen tube walls, their primary composition being cellulose.     

Cotton embryogenesis: The pollen cytoplasm

Summary The ultrastructure and composition of cotton (Gossypium hirsutum) pollen, exclusive of the wall, was examined immediately before and after germination. The pollen grain before germination consists of two parts: the outer layer and a central core. The outer layer contains large numbers of mitochondria and dictyosomes as well as endoplasmic reticulum (ER). The core contains units made of spherical pockets of ER which are lined with lipid droplets and filled with small vesicles; the ER is rich in protein and may contain carbohydrate while the vesicles are filled with carbohydrate. Starch-containing plastids are also present in the core as are small vacuoles. The cytoplasm of the pore regions contains many 0.5 spherical bodies containing carbohydrate. After germination the ER pockets open and the lipid droplets and small vesicles mix with the other portions of the cytoplasm. With germination the pore region becomes filled with mitochondria and small vesicles. The vegetative nucleus is large, extremely dense and contains invaginations filled with coils of ER. A greatly reduced nucleolus is present in the generative cell which is surrounded by a carbohydrate wall. The cytoplasm of the generative cell is dense and contains many ribosomes, a few dictyosomes and mitochondria, many vesicles of several sizes, and some ER. No plastids were identified. The generative nucleus is also dense with masses of DNA clumped near the nuclear membrane. An unusual tubular structure of unknown origin or function was observed in the generative cell.     

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.     

川百合精细胞的超微结构(英文)

川百合与朱顶红花粉管中的生殖细胞分裂行为非常不同。诸如：染色体行为、微管的组织形式和分布、包括着丝点、微管形成的时间,纺锤体的形状及间期周质微管网络在生殖细胞分裂过程中消失与否等。但这两种细胞具有某些共性,包括在有丝分裂前期缺乏早前期带微管（ＰＰＢ）,末期形成细胞板等。这两种植物精细胞的结构应有较大差异。我们曾报道了朱顶红精细胞的超微结构,本文详细从超微结构方面描述了川百合精细胞的特征。川百合花粉管的萌发采用半离体活体培养方式。１１～１８小时后,ＤＮＡ荧光染料Ｈｏｅｃｈｓｔ３３２５８和醋酸地衣红染色检查花粉管中生殖细胞和精细胞发育时期。切取含有分裂的生殖细胞和精细胞的花柱部分,按曾报道的方法固定、包埋、切片、染色及观察。在所有检查的花粉管中,两精子均前后排列（Ｆｉｇ．１～３）,营养核前导并靠近花粉管顶端（Ｆｉｇ．２,３）。Ｈ３３２５８染色可见两精核间以ＤＮＡ联系（Ｆｉｇ．３）。两个新形成的精核彼此分离（Ｆｉｇ．１）,后来又相互靠近,并维持一定距离（Ｆｉｇ．３）。偶尔一对精子与营养核靠近（Ｆｉｇ．２）。两精细胞被一共同的细胞壁连接,他们不仅被自己的质膜也被营养细胞的质膜包围构成周质。周质平坦光滑。共同壁横向     

Growth and cellular organization of Arabidopsis pollen tubes in vitro

Tricellular pollen tubes of Arabidopsis thaliana were cultured in vitro on solid media and studied with respect to growth, cellular organization and ultrastructure, cytoskeletal organization, organelle movement, deposition and structure of the wall and the occurrence of coated pits, all elements assumed to be relevant for tip growth. For our ultrastructural studies we used freeze fixation and freeze substitution. Although Arabidopsis pollen tubes are broadly similar to those of bicellular species such as Nicotiana tabacum and Lilium spec. and in vivo grown pollen tubes of Arabidopsis, some differences occurred. The density of the equally distributed, relatively small (85 nm) secretory vesicles (SV) in the tip is low (five/µm ²). In between the SV of the tip, membranous material, possibly smooth endoplasmic reticulum, fragments of rough endoplasmic reticulum and loose ribosomes are present. The wall in the tip is not amorphous but layered and a secondary wall is formed already in the flanks of the tip. The general pattern of organelle motion is reverse fountain-like, but individual organelles move in distinct lanes at speeds of up to 2 µm/s, and about half of the organelle population shows a moderate velocity or Brownian movement. These properties are discussed in relation to the low growth rate (10 µm/h) of Arabidopsis pollen grown in vitro. The two similar sperm cells are closely attached and are always found near the vegetative nucleus. No surrounding wall and no cytoskeletal elements were obvious in the sperm cells. The preferential location of the mitochondria at the wall and the large (up to 400 nm) coated pits are unique for angiosperm pollen tubes. The size of the coated pits may allow not only membrane retrieval but also pinocytosis.     

Why are plastids maternally inherited in epilobium? Ultrastructural observations during microgametogenesis

We have investigated the sequential stages of microgametogenesis by electron microscopy, to determine the basis of maternal inheritance of plastids in Epilobium. The development of both the vegetative and generative cells has been followed using a semi-artificial growth system for pollen tubes. The generative cells inside the pollen grain contains numerous mitochondria, 5–8 proplastids, and, in contrast to the vegetative cytoplasm, only a few vacuoles. When the generative cell has divided into the two sperm cells inside the pollen tube, small vesicles deriving from dicytosome cisternae become abundant. These vesicles appear to form vacuoles by fusion which then contain remnants of fibrillar, globular or membranaceous material. It is suggested that this material derives from proplastids as the proplastids disappear either before or shortly after the generative cell has divided, concurrently with the appearance of the ‘remnants’ in the vacuoles. The mitochondria of the sperm cells remain intact.