土麦冬离体萌发花粉管中生殖细胞与营养核的动态变化

主要报道了土麦冬人工培养萌发花粉管中生殖细胞与营养核的动态变化。多数花粉管中,生殖细胞与营养核贴合后,开始进行有丝分裂,贴合时,营养核略呈弥散状态。在分裂早中期,生殖细胞与营养核分开,从贴合到分开大约经历３－５ｈ,精子形成后,不与营养核连接。ＤＡＰＩ对生殖细胞的有丝分裂有抑制作用。少数花粉管中,生殖细胞核进行无丝分裂,有缢裂和劈裂两种方式。生殖细胞核发生缢裂的花粉管中,未观察到生殖细胞与营养核的贴     

AN AUTORADIOGRAPHIC STUDY OF RNA SYNTHESIS DURING POLLEN EMBRYOGENESIS IN HYOSCYAMUS NIGER (HENBANE)

RNA synthesis during pollen embryogenesis in cultured anther segments of Hyoscyamus niger (henbane) has been followed by autoradiography of ³H-uridine incorporation. Embryogenic divisions were initiated in binucleate pollen grains in which the generative nucleus or both generative and vegetative nuclei synthesized RNA. When the first haploid mitosis in culture resulted in pollen grains with two nearly identical nuclei, those in which both nuclei synthesized RNA became embryogenic. Binucleate pollen grains in which ³H-uridine incorporation was confined exclusively to the vegetative nucleus gradually became starch-filled and nonembryogenic. Based on the degree of involvement of the vegetative nucleus in embryoid formation, some differences were noted between the counts of autoradiographic silver grains over cells cut off by the generative and vegetative nuclei during progressive embryogenesis. The possible significance of RNA synthesis in the nuclei of binucleate pollen grains in determining the pathway of embryogenic divisions is discussed.     

Electron microscopic ammonical silver reaction forTradescantia pollen grain

Summary The postformalin ammonical silver reaction (ASR) for basic nuclear proteins was applied to both the generative and vegetative nuclei ofTradescantia pollen grains and examined with the electron microscope. The ASR deposit was usually observed mainly in the dense chromatic regions of both the generative and vegetative nuclei. Since a large amount of dense chromatic regions was observed in the generative nucleus than the vegetative ones in late or mature pollen grains, as a results, the increased amount of the ASR deposit was revealed in the generative nucleus.     

An autoradiographic study of RNA synthesis during maturation and germination of pollen grains ofHyoscyamus niger

Summary The pattern of RNA synthesis during maturation and germination of pollen grains ofHyoscyamus niger was studied using³H-uridine autoradiography. Incorporation of label during pollen maturation was periodic with peak RNA synthesis occurring in the uninucleate, nonvacuolate pollen grains and in the vegetative cell of the bicellular pollen grains. During the early stages of germination, isotope incorporation occurred predominantly in the nucleus of the vegetative cell with little or no incorporation in the generative cell. With the appearance of the pollen tube, incorporation of³H-uridine in the vegetative cell nucleus decreased and completely disappeared at later stages of germination. No incorporation of isotope was observed in the sperms formed in the pollen tube by the division of the generative cell. From a comparison of the results of this study with those of previous works on RNA synthesis during pollen embryogenesis in cultured anthers ofH. niger, it is concluded that in contrast to embryogenic development, there is no requirement for sustained RNA synthesis by the generative cell nucleus for normal gametophytic development.     

Ultrastructure and Germination Percentage of Crocus biflorus Miller subsp. biflorus (Iridaceae) Pollen

Pollen of Crocus biflorus Miller subsp. biflorus from natural habitats of Tusculum (Frascati, near Rome, Italy) has been studied in order to compare its structure and physiology to pollen of other Crocus species belonging to the Crocus sativus group. Mature pollen grains are rounded, 60 μm in diameter, in-aperturate (but with surface incisions where exine is lacking). DAPI staining reveals a spindle-shaped generative nucleus which is intensely fluorescent, and vegetative nucleus which is less fluorescent, and is elongated with numerous lobes. At anthesis the pollen is bicellular, but about 2% of tricellular grains occur among the pollen grains released from the anthers as well as on both naturally or handpollinated stigmas. Pollen germination is low in vitro, but higher in vivo. The pollen tubes are of normal shape. An electron-dense surface coat is sometimes visible on the exine, which in many cases, is detached from the exine. The vegetative cytoplasm is very rich in glycolipid bodies surrounded by endoplasmic reticulum. The generative cell has a lobed cell wall and is surrounded by the vegetative nucleus.     

Histone H4 acetylation and DNA methylation dynamics during pollen development

Summary The first pollen mitosis results in generative and vegetative cells which are characterised by a striking difference in their chromatin structure. In this study, histone H4 acetylation and DNA methylation have been analysed during pollen development inLilium longiflorum. Indirect immunofluorescence procedures followed by epifluorescence and laser scanning microscopy enabled a relative quantification of H4 acetylation and DNA methylation in microspores, immature binucleate pollen, mature pollen, and pollen tubes. The results show that histone H4 of the vegetative nucleus, in spite of its decondensed chromatin structure, is strongly hypoacetylated at lysine positions 5 and 8 in comparison with both the original microspore nucleus and the generative-cell nucleus. These H4 terminal lysines in the vegetative nucleus are, however, progressively acetylated during the following pollen tube growth. The DNA methylation analysis inversely correlates with the histone acetylation data. The vegetative nucleus in mature pollen grains is heavily methylated, but a dramatic nonreplicative demethylation occurs during the pollen tube development. Changes neither in H4 acetylation nor in DNA methylation have been found during development of the generative nucleus. The results obtained indicate that the vegetative nucleus enters the quiescent state (accompanied by DNA hypermethylation and H4 underacetylation) during the maturation of pollen grain which enables pollen grains a long-term survival without external source of nutrients until they reach the stigma.     

Pollen ultrastructure in anther cultures of Datura innoxia. III. Incomplete microspore division.

During the microspore division in Datura innoxia, the mitotic spindle is oriented in planes both perpendicular (PE) and oblique (OB) to the spore wall against which the nucleus is situated. However, irrespective of polarity, the usual type of hemispherical wall is laid down at cytokinesis and isolates the generative cell from the rest of the pollen grain (type A). In PE spores the vegetative nucleus initially occupies a central position in the pollen grain, whereas in OB spores the vegetative nucleus lies at the periphery of the grain close to the generative cell. In anther cultures initiated just before the microspore division is due to take place, no marked change can be observed in either orientation or symmetry of the mitotic spindle when the spores divide. In some, however, cytokinesis is disrupted and deposition of the hemispherical wall arrested. In the absence of a complete wall, differentiation of the generative cell cannot take place and binucleate pollen grains are formed having 2 vegetative-type nuclei (type B). The 2 nuclei in the B pollens are always situated against the pollen-grain wall, suggesting that the disruption phenomenon is related to the OB spores. The incomplete wall always makes contact with the intine on the intine-side of the spindle. Wall material may be represented merely as short stubs projecting out from the intine into the cytoplasm, in which event the 2 nuclei lie close to each other and are separated by only a narrow zone of cytoplasm. In other grains the wall is partially developed between the nuclei and terminates at varying distances from the tonoplast; in these, the nuclei are separated by a wider zone of cytoplasm. The significance of these binucleate grains in pollen embryogenesis is discussed.     

Ultrastructural studies on plastids of generative and vegetative cells inLiliaceae 3. Plastid distribution during the pollen development inGasteria verrucosa (Mill.) Duval

Summary This paper describes the development of pollen grains ofGasteria verrucosa from the late microspore to the mature two-cellular pollen grain. Ultrastructural changes and the distribution of plastids as a result of the first pollen mitosis have been investigated using light and electron microscopy. The microspores as well as the generative and the vegetative cell contain mitochondria and other cytoplasmic organelles during all of the observed developmental stages. In contrast, the generative cell and the vegetative cell show a different plastid content. Plastids are randomly distributed within the microspores before pollen mitosis. During the prophase of the first pollen mitosis the plastids become clustered at the proximal pole of the microspore. The dividing nucleus of the microspore is located at the distal pole of the microspore. Therefore, the plastids are not equally distributed into both the generative and the vegetative cell. The possible reasons for the polarization of plastids within the microspore are briefly discussed. The lack of plastids in the generative cell causes a maternal inheritance of plastids inGasteria verrucosa.     

Isolation of generative cells and their protoplasts from pollen ofLilium longiflorum

Summary Methods are described for the isolation of large quantities of generative cells and their protoplasts from the pollen ofLilium longiflorum. First, large numbers of pollen protoplasts were enzymatically isolated from immature pollen grains. When they were gently disrupted mechanically, the pollen contents including spindle-shaped generative cells were released. The generative cells were separated from other structures by Percoll density gradient centrifugation. They were nearly spherical, but had a callosic cell wall. The isolated generative cells were then re-treated in enzyme solution to yield authentic protoplasts. The generative cell protoplasts, gametoplasts, were uniform in size and contained a condensed haploid nucleus with relatively little cytoplasm.     

Apoptosis-like degradation of pollen grains in siberian squill related to the lack of low temperatures during their development

Low temperature is necessary for completing the cycle of anther development in early-spring ephemeroids. Pollen grains were investigated in Scilla sibirica L. growing under natural conditions in a park and taken to a greenhouse for the cold season. In control plants grown in the open ground, the development of microspores was normal. The plants transferred to the greenhouse sharply differed from control material. By the middle of November, the aggregations of condensed chromatin were formed near the nucleus envelope of their generative cells. In some mitochondria, the system of cristae was reduced. In December, all the mitochondria showed a reduced system of cristae. In the matrix of some mitochondria with ruptured envelopes, rather large vesicles were detected. In the vegetative and generative cells, autophagic vacuoles were formed. They also occurred in the nucleus itself; as a result, the cells of pollen grains became much more vacuolated. In January, only the products of protoplast lysis were detected in all the pollen grains. It was concluded that the lack of low temperatures induced apoptosis-like degradation of the cells of Siberian squill pollen grains.     

Heritable paternal cytoplasmic organelles in alfalfa sperm cells: ultrastructural reconstruction and quantitative cytology.

Sperm cells within pollen grains and pollen tubes of alfalfa (Medicago sativa L.) were observed at the ultrastructural level, and their plastid DNA was detected by DAPI (4,6-diamidino-2-phenylindole) staining. One sperm pair within the pollen grain and three sperm pairs within pollen tubes were reconstructed in three-dimensions from serial ultrathin sections. The two sperm cells are linked by cytoplasmic bridges in both pollen grains and tubes, and the vegetative nucleus is closely associated with the sperm cells within the pollen tube. The number of plastids and plastid nucleoids (DNA aggregates) in the sperm cell pair, collectively, is not significantly different from that in the generative cell; however, over 60% of the sperm cell plastids contain no DNA detectable with DAPI. The mean number of mitochondria in sperm cells is reduced from that in the generative cell (from 54 to 17), which suggests that paternal mitochondrial inheritance probably does not occur in the genotype investigated. Sperm cells of a pair may vary in their shape within the pollen grain and tube, but the number of plastids and mitochondria is not significantly different between the sperm cells. Therefore, heterospermy is not a factor determining cytoplasmic inheritance patterns in this species.     

Pollen Bud Formation and its Role in Ophiorrhiza spp.

The anther in Ophiorrhiza is dithecous and tetralocular, itsdevelopment being of the dicotyledonous type. The anther wallcomprises epidermis, endothecium, middle layer and secretorytapetum. The pollen grains are tricolpate and triporate. Themicrospore nucleus undergoes division to form a vegetative nucleusand a generative nucleus and protrusions (pollen buds) are formedfrom the germ pores after the first division of the microsporenucleus. The vegetative nucleus moves into one of these budsor first breaks into a number of irregularly sized nuclear particleswhich enter into one, two or into all three buds, where theydegenerate. Then the pollen buds are separated and the generativenucleus divides inside the pollen tube to form two sperms. Ophiorrhiza harrisiana, Ophiorrhiza hirsutula, microsporogenesis, pollen buds, vegetative nucleus     

The Comportment of the Vegetative Nucleus and Generative Cell in the Pollen and Pollen Tubes of Helleborus foetidus L

It has been reported that in species of Plumbaginaceae, Chenopodiaceae,Cruciferae and Amaryllidaceae a ‘male germ unit’is formed in which the two male gametes remain inter-connected,with one of the pair linked intimately to the vegetative nucleus.In two species the unit has been shown to remain intact in thepollen tube, and some accounts imply that it is polarized inits movement, the vegetative nucleus leading in the tube. Evidence given in this paper indicates that such a unit is unlikelyto be present in Helleborus foetidus L. (Ranunculaceae). Applicationof an optical sectioning technique has shown that at no timeis there a persistent linkage between the generative cell andthe vegetative nucleus in unhydrated, hydrated and germinatingpollen, nor is one present in the early pollen tube. Furthermore,no inter-connections between the two entities were seen in protoplastsfrom living, hydrated and incipiently germinating grains isolatedmechanically in an osmotically balancing medium. Following germination,the vegetative nucleus leaves the grain in advance of the generativecell in most instances, but in the samples examined the generativecell led in about 30 per cent of the tubes. Assembling a polarisedmale germ unit in these circumstances would require (a) theformation of an inter-connection between the vegetative nucleusand the generative cell or one of the gametes derived from itduring passage through the tube, and (b) where the generativecell initially leads in the tube, an exchange in relative positions.It is considered improbable that these conditions could consistentlybe met. Mature, incipiently germinating pollen of H. foetidus releasesa fibrillar component when extruded into suitable media. Websor clusters of fibrils are commonly seen to be associated withboth the vegetative nucleus and the generative cell. The possibilitythat the fibrils are composed of aggregates of microfilamentsis considered. Helleborus foetidus L., pollen germination, generative cell, vegetative nucleus, male germ unit     

Mitosis and Amitosis of Generative Cell Nuclei in Artificially Germinated Pollen Tubes in Zephyranthes candida(Lindl.)Herb.

This paper deals with the comportmem of the vegetative nucleus and its spatial association with the generative cell and sperm cells in the artificially germinated pollen tubes of Zephyranthes candida (Lindl.) Herb. before and after generative cell mitosis with the use of DNA-specific fluochrome 4′,6-diamidino-2-phenylindole (DAPI). The induction of amitosis and abnormal mitosis of generative cell nuclei by cold-pretreatment of the pollen prior to germination was studied in particular. In normal case, the generative cell, after appressing to the vegetative nucleus for certain time, underwent mitosis to form two sperms, while the vegetative nucleus became markedly elongated, diffused, and exhibited blurring of its fluorescence. After division, a pair of sperms remained shortly in close connexion with the vegetative nucleus. Then the vegetative nucleus returned to its original state. In the pollen tubes germinated from cold-pretreated pollen, amitosis of some generative cell nuclei were frequently observed. Amitosis took place via either equal or unequal division with a mode of constriction. During amitosis, the dynamic change of vegetative nucleus and its intimate association with generative cell afore described did not occur. Sperm nuclei produced from amitosis could farther undergo amitisis resulting in micronnclei. Factors affecting the amitosic rate of generative cells, such as pollen developmental stage, temperature and duration of cold-pretreatment, were studied. Besides amitosis, cold-pretreatment also induced some abnormal mitotic behavior leading to the formation of micronuclei. Based on our observations and previously reported facts in other plant materials, it is inferred that the vegetative nucleus plays an important role in normal mitosis of generative cell and development of sperms.     

Absence of the nucleolar constriction in the division of the generative nucleus of Haplopappus gracilis

The nucleolar constriction which is a structural characteristic of the chromosomes of Haplopappus gracilis (n = 2) is not formed in the division of the generative nucleus in pollen grains. Some brief discussions are given on its absence.     

iaaM基因在烟草花粉中的表达及其在花粉发育中的作用

试验利用花粉特异表达的启动子(Lat52)和绒毡层特异表达的启动子(TA29)引导外源生长素合成代谢基因(iaaM)在烟草花粉中表达以研究生长素在花粉发育中的作用。转Lat52-iaaM基因或转TA29-iaaM基因烟草在形态上表现出变异,如从茎上形成不定根,叶呈卷曲状等典型的生长素过量表达的性状。另外,与对照相比,转基因烟草花药中IAA水平显著增加,且植株矮化,开花期推迟,有的转基因烟草未能开花。上述现象表明:Lat52和TA29启动子的表达并不仅限于花粉或绒毡层,或者说这两个启动子的表达有些泄漏。转基因烟草的花药形状有较大的变异,早期的每个花药中花粉数明显减少,但这些花粉可被醋酸一洋红染色。所有能开花的转基因烟草均可收到种子,但收自某些转基因株系的种子不能萌发。所有这些结果表明生长素在花粉发育过程中起重要作用,过量的生长素会导致花粉发育的异常。     

Confocal Microscopic Observations on Actin Filament Distribution in Lily Pollen Protoplasts

Actin filaments (F-actin) were localized in the isolated pollen protoplasts of lily using TRITC-phalloidin probe and confocal microscopy. Two kinds of pollen protoplasts were examined: one from pollen grains of non-dehiscent anthers(referred to as ‘nearly mature’ pollen); and the other from pollen grains of just dehiscent anthers(referred to as ‘just mature’ pollen). In the cytoplasm of the pollen protoplasts of the ‘nearly mature’ pollen there was a very well organized actin network made up of thick actin bundles. Two types of bundle connections were seen in the network; namely ‘branch’ connections and 'junction' connections. The ‘branch’ connection (or branching points) was formed due to branching or merging of bundies. The ‘junction’ connection (or 'junction' point) had two or more bundles associated with it. Some of the ‘junction’ points might be actin filament organization: centres. The generative cell in iht pollen protoplasts of the ‘nearly mature’ pollen also contained an actin network. But this network was structurally quite loose and the pundles made up the network were short and thick. In the cytoplasm of the pollen protoplasts of the ‘just mature’ pollen the actin net work was more densely packed. The bundles made up the network were also thinner. The actin network in the generative cell was, however, less densely packed. If the pollen protoplasts from both the ‘nearly mature’ and the 'just mature' pollen grains were transferred from a B5 medium into a Brewbaker and Kwack medium supplemented with sucrose, protoplasts rapidly (i.e. within 2 to 3 hours) developed vacuoles and transvacuolar strand. In these va cuolated protoplasts the vegetative nucleus andthe generative cell became tightly surrounded by a new actin network. In the transvacuolar strands there were numerous actin bundles. The “ends” of some of these bundles appeared to be tightly attached to the protoplast membrane indicating that some kind of structures might be present in the protoplast membrane for actin filament attachment.     

Isolation and separation of S-competent and S-incompetent nuclei from Tradescantia pollen grains

A method is described, using discontinuous sucrose density gradients, for the separation of generative and vegetative nuclei from young Tradescantia pollen grains during the period of DNA synthesis. The nuclei are obtained in 20–30% yield from the pollen grains; they are 85–95% pure (generative) and 70–80% pure (vegetative).     

A lily pollen ASR protein localizes to both cytoplasm and nuclei requiring a nuclear localization signal

LLA23, an abscisic acid-, stress- and ripening-induced (ASR) protein, was isolated previously from lily ( Lilium longiflorum ) pollen. Close examination of the C-terminus of this ASR protein revealed the presence of basic regions reminiscent of a nuclear localization signal (NLS). Fluorescence microscopy studies using green fluorescent protein (GFP) fusion proteins indicated that the bipartite NLS in LLA23 exhibited nuclear localization properties. Accordingly, mutations in the NLS motifs of LLA23 defined two regions, either of which was necessary for partial nuclear targeting and both of which were required for complete nuclear localization. In addition, oligonucleotide-directed mutagenesis identified lysine residues within the NLS necessary for nuclear localization. Immunogold localization confirmed that the protein was located to both the cytoplasm and nucleus of generative and vegetative cells of pollen grains; the generative nuclei showed the highest number of LLA23 labelling. The possible function of ASR proteins in both the cytoplasm and nuclei of pollen grains is discussed.