Relationship between the generative cell and vegetative nucleus in pollen tubes of Nicotiana tabacum

Summary Fluorescence microscopy was used to visualize microtubules (Mts) and chromatin in an effort to further clarify the relationship between the generative cell (GC) and vegetative nucleus (VN) in pollen tubes of tobacco. Prominent Mt bundles are present in one or more GC extensions that can be finger-like or lamellar in form. While the VN is positioned distal to the GC in most cases, it can also straddle the cell or lie proximal to it. In all cases, however, extensions embrace, penetrate or clasp the VN. GC Mts are reorganized during the formation of the mitotic apparatus, and cell extensions are fully or partially withdrawn. By telophase in many pollen tubes, the VN shifts to a more proximal position and appears to adhere to the region of the GC containing the phragmoplast. Application of oryzalin leads to the disorganization of Mts, changes in cell shape, including the loss or alteration of cell extensions, and separation of the GC and VN in some cases. However, the position and polarity of the VN is maintained in most pollen tubes. The results indicate that GC Mts and cell extensions play a role in the association with the VN. However, the relationship appears to be controlled by other factors as well. Attention should now be directed at potential interactions involving the VN envelope, vegetative plasma membrane, GC plasma membrane and extracellular matrix.Abbreviations GC Generative cell - MGU male germ unit - Mt microtubule - VN vegetative nucleus     

Changes in volume,surface area,and frequency of nuclear pores on the vegetative nucleus of tobacco pollen in fresh,hydrated, and activated conditions

The vegetative nucleus (VN) of Nicotiana tabacum L. has been qualitatively and quantitatively studied in fresh, hydrated, and activated pollen. Techniques included the use of optical sectioning by confocal scanning laser microscopy to obtain volume and surface area measurements, and stereoscopic pairs; and freeze-etch electron microscopy to estimate the frequency of nuclear pores per m² in the vegetative nucleus. Several morphological changes were observed to occur in pollen grain nuclei during the early processes of tube growth. In freshly dehisced pollen grain, the vegetative and generative nuclei were side by side, but following hydration and activation of the grain, the elongated generative nucleus became partially surrounded by the vegetative nucleus. It was found that during hydration, the surface area of the vegetative nucleus increased and there was a decrease in the frequency of nuclear pores. The calculated total number of pores remained similar. After activation and pollen-tube growth, the vegetative nucleus retained the same surface area as in the hydrated state but the frequency of nuclear pores decreased; therefore, the calculated total number of pores was significantly lowered. When considered alongside complementary biochemical data, these morphological results indicate that RNA production in the vegetative nucleus decreases following germination.Abbreviations VN vegetative nucleus (nuclei) - GN generativenucleus - GC generative cell - CSLM confocal scanning laser microscope We acknowledge research support by the Biotechnology Action Programm of the Commission of European Communities, and CNR for the fellowship awarded to Dr. Wagner. We would also like to thank Mrs. C. Faleri for the expert technical help.     

The ultrastructure of polymorphic pollen grains of Canna indica L.

Summary Our investigations on Canna indica L. indicate that the pollen of this species is polymorphic: there are two types of pollen — a larger type and a comparatively smaller type. Transmission electron microscopy (TEM) revealed the presence of small vacuoles containing tannic substances in the generative cell (GC) of the larger grains: the GC of the mature grain contained a higher quantity of tannins than the GC of the immature grain. Mitochondria, lipid bodies, rough endoplasmic reticulum (RER) and microtubular bundles were present in the cytoplasm of the GC. Numerous mitochondria, lipid bodies and plastids were also present in the vegetative cell (VC), with the mitochondria clustered around the vegetative nucleus. The plastids were observed to be associated with the RER cisterns. During the maturation process, the number of starch grains contained in the plastids decreased.     

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.     

Ultrastructural Observation on Microtubules of the Generative Cell in Amaryllis Germinated Pollens and Pollen Tubes

The organization of microtubules (MTs) in the generative cell (GC) of germinated pollen and pollen tube in Amaryllis vittata Ait. has been studied with electron microscopy. At the beginning of pollen germination, the GC is long elliptic in shape, and is surrounded by its own membrane and also by that of the vegetative cell (VC) ,both of which appear undulated. In cross section, the GC appears roundish and has many lobes. The MT system of GC is mainly organized in bundles, but single MTs can also be observed. The MT bundles are generally located in the lobes, directly beneath the plasma membrane of the cell. These MT bundles orientate along the longitudinal axis of the cell. They are formed by aggregation of 5–6 MTs at least,more often about 30 MTs. In the bundles the MTs are often linked to each other by "cross-bridge". The single tubules in the eytopiasm distribute randomly in different orientations. When the GC has migrated into the pollen tube after germination ,it becomes elongated and has cytoplasmic extensions both in the anterior and posterior end of the cell. The organization of MTs of the GC in pollen tube is similar to that in the germinated pollen grain,but the number of MTs in a bundle often increases to 50–60. In the bundle the "cross-bridges" between the MTs which always link 3–5 MTs, are still seen clearly. Positional shift between the GC and Vegetative nucleus (VN) may take place during the growth of pollen tube. The physical association between GC and VN may be demonstrated some ultrastructural figures. It may be seen that irregular cytoplasmic extensions in the anterior end of the GC is always enclosed by the VN and the projections of the cytoplasmic extensions lie within enclaves of the VN. There are many MTs sheets in the lobes or extensions in the cytoplasm of the GC. Thus the present study demonstrates that MTs have an important role in maintaining the peculiar shape of the GC and the close association between GC and VN. However, it seems that the MTs are probably also engaged in the movement of the GC during pollen growth.     

Ultrastructure of the vegetative cell ofBrassica napus pollen with particular reference to microbodies

Summary The ultrastructure of the vegetative cell ofBrassica napus tricellular pollen grains, just before anthesis with standard chemical fixation, is reported. The vegetative cell may be regarded as a highly differentiated and metabolically active fat-storage cell. It contains many mitochondria with a well developed internal membrane system, starchless plastids, microbodies, lipid bodies, dictyosomes and numerous vesicles thought to originate from the dictysomes. Rough endoplasmic reticulum organized in stacks of cisternae is also spatially associated with certain organelles, mainly lipid bodies, microbodies and plastids. There are also randomly distributed polyribosome areas. The microbodies are mainly polymorphic in shape and are often observed in contact with lipid bodies. The above spatial relationship implies that the microbodies may have a glyoxysomal function. In the late period of vegetative cell maturation, the microbodies are probably involved in the process of glyconeogenesis in which the conversion of lipid reserves to sugar takes place.Abbreviations VC vegetative cell - VN vegetative nucleus - SC sperm cell - M mitochondria - MB microbodies - L lipid body - P plastid - D dictyosomes     

Ultrastructure of freeze-substituted pollen tubes ofLilium longiflorum

Summary In view of the importance of the lily pollen tube as an experimental model and the improvements in ultrastructural detail that can now be attained by the use of rapid freeze fixation and freeze substitution (RF-FS), we have reexamined the ultrastructure of these cells in material prepared by RF-FS. Several previously unreported details have been revealed: (1) the cytoplasm is organized into axial slow and fast lanes, each with a distinct structure; (2) long, straight microtubule (MT) and microfilament (MF) bundles occur in the cytoplasm of the fast lanes and are coaligned with every organelle present; (3) the cortical cytoplasm contains complexes of coaligned MTs, MFs, and endoplasmic reticulum (ER); (4) the cortical ER is arranged in a tight hexagonal pattern and individual elements are closely appressed to the plasma membrane with no space between; (5) mitochondria and ER extend into the extreme apex along the flanks of the pollen tube, and vesicles and ER are packed into an inverted cone-shaped area at the center of the apex; (6) MF bundles in the tip region are fewer, finer, and in random orientation in comparison to those of the fast lanes; (7) the generative cell (GC) cell wall complex contains patches of plasmodesmata; (8) The GC cytoplasm contains groups of spiny vesicles that are closely associated with and seem to be fusing with or pinching off from mitochondria, and (9) the vegetative nucleus (VN) contains internal MT-like structures as well as numerous cytoplasmic MTs associated with its membrane and also located between the VN and GC.Abbrevations CF chemical fixation - ER endoplasmic reticulum - GC generative cell - MF microfilament - MT microtubule - PD plasmodesmata - PM plasma membrane - RF-FS rapid freeze fixation-freeze substitution - VN vegetative nucleus     

Role of microtubules in the movement of the vegetative nucleus and generative cell in tobacco pollen tubes

The germination and growth of pollen grains of Nicotiana tabacum and N. alata with the anti-microtubule drug oryzalin retarded significantly the movement of the vegetative nucleus (VN) and the generative cell (GC) from the grain to the tube apex but had no effect on pollen tube elongation. In N. tabacum, only 11% and 48% of the pollen tubes treated with oryzalin for 6 h and 12 h, respectively, had the VN and GC in the tube mainly in its middle part. In corresponding control materials, 79% and 99% of pollen tubes contained the VN and GC close to the apex. Indirect immunofluorescence microscopy and related studies of the tubes grown in the presence of oryzalin revealed complete absence of microtubules (MTs) but apparently intact microfilaments (MFs). These results suggested that the movement of VN and GC from the grain into the tube is possible when no MTs but only MFs are present, but the movement is then slow. In control tubes, the parallel orientation of MT bundles and extensions of VN were interpreted to represent the structural organization needed for the MT-dependent movement of VN.     

Populations of plastids and mitochondria during male reproductive cell maturation in Nicotiana tabacum L.: A cytological basis for occasional biparental inheritance

The dynamics of plastid and mitochondrial populations in male reproductive cells of tobacco (Nicotiana tabacum L.) were examined during development using serial ultrathin sections and transmission electron microscopy to reconstruct 58 generative cells and 31 sperm cells at selected stages of maturation from generative cell formation through gametic fusion. The first haploid mitosis resulted in incomplete exclusion of plastids providing an average of 2.81 plastids and 82.7 mitochondria for each newly formed generative cell. During generative-cell maturation, plastid content decreased to an average of 0.48 plastids/generative cell at anthesis owing to autophagy of organelles. Plastids were present in low frequency within generative and sperm cells in the pollen tube and appeared to be transmitted, according to observations immediately prior to fertilization. This forms a cytological basis for genetic reports of occasional biparental plastid inheritance. In contrast, mitochondria were transmitted in larger numbers, and approximately 80 mitochondria per generative cell or sperm cell pair were retained throughout development. This provides a potentially stable source for the transmission of male mitochondrial DNA, if present at fertilization.Abbreviations GC generative cell - SC sperm cell We thank Dr. Frank J. Sonleitner, for helpful suggestions on the statistical calculations and Dr. Bing-Quan Huang for technical assistance in the preparation of embryo sacs during fertilization. This research was supported in part by U.S. Department of Agriculture grant 91-37304-6471. We gratefully acknowledge use of the Samuel Roberts Noble Electron Microscopy Laboratory of the University of Oklahoma.     

Brassica napus pollen development during generative cell and sperm cell formation

Summary Brassica napus pollen development during the formation of the generative cell and sperm cells is analysed with light and electron microscopy. The generative cell is formed as a small lenticular cell attached to the intine, as a result of the unequal first mitosis. After detaching itself from the intine, the generative cell becomes spherical, and its wall morphology changes. Simultaneously, the vegetative nucleus enlarges, becomes euchromatic and forms a large nucleolus. In addition, the cytoplasm of the vegetative cell develops a complex ultrastructure that is characterized by an extensive RER organized in stacks, numerous dictyosomes and Golgi vesicles and a large quantity of lipid bodies. Microbodies, which are present at the mature stage, are not yet formed. The generative cell undergoes an equal division which results in two spindle-shaped sperm cells. This cell division occurs through the concerted action of cell constriction and cell plate formation. The two sperm cells remain enveloped within one continuous vegetative plasma membrane. One sperm cell becomes anchored onto the vegetative nucleus by a long extension enclosed within a deep invagination of the vegetative nucleus. Plastid inheritance appears to be strictly maternal since the sperm cells do not contain plastids; plastids are excluded from the generative cell even in the first mitosis.     

Microtubules are involved in maintaining the cellular polarity in pollen tubes ofNicotiana sylvestris

Summary The polarity of a growing pollen tube is clearly reflected by a distinct zonation of the cytoplasmic content. The vegetative nucleus and the generative cell (GC) are located in the tip region of the tube, and the basal cytoplasmic portion is highly vacuolated. Using pollen tubes ofNicotiana sylvestris Spegazz. & Comes grown in vitro, we examined the effects of varying concentrations of the microtubule inhibitors colchicine and propham. The depolymerization of the cortical microtubules by 25 M colchicine led to a disorganization of the cytoplasm, i.e., vacuolization of the tip region, and to a deranged position of both the vegetative nucleus and the generative cell. The same concentration of colchicine inhibited tube growth by 10–20% of the control. Mitosis of the GC was not affected. Only from concentrations of 200 M the configuration of the GC's microtubules was altered and an inhibition of mitosis was observed. At this concentration the disorganization of the cytoplasm was always reversible, but neither inhibition of mitosis nor derangement of the nuclear positioning was. At 1,800 M colchicine, pollen tube growth was inhibited by 50% of the control. Using propham, the same three steps of action were observed, although propham proved to be about a hundred times more effective than colchicine. We conclude that the cortical microtubules of the pollen tube are involved in maintaining cellular polarity, probably as a part of a heterogeneous cytoskeletal network including also microfilaments and membranous elements. Nuclear positioning seems to be dependent on both, the tube's cortical and the GC's microtubules. A possible involvement of the extracellular matrix in maintaining intracytoplasmic polarity is suggested.Abbreviations DAPI 4,6-diamidino-2-phenylindole - EGTA ethyleneglycol-bis-(aminoethyl ether) tetraacetic acid - GC generative cell - MF microfilament - MT microtubule - PEM-buffer 50 mM PIPES, 1 mM EGTA, 2 mM MgSO₄, pH 6.9 - PBS phosphate buffered saline - PIPES piperazine-bis-ethanesulphonic acid - PTG-test pollen tube growth test - VN vegetative nucleus Dedicated to Professor Peter Sitte on the occasion of his 65th birthday     

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.     

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.     

The organization of microtubules during generative-cell division inConvallaria majalis

Summary The organization of the microtubule cytoskeleton in the generative cell ofConvallaria majalis has been studied during migration of the cell through the pollen tube and its division into the two sperm cells. Analysis by conventional or confocal laser scanning microscopy after tubulin staining was used to investigate changes of the microtubule cytoskeleton during generative-cell migration and division in the pollen tube. Staining of DNA with 4,6-diamidino-2-phenylindole was used to correlate the rearrangement of microtubules with nuclear division during sperm cell formation. Before pollen germination the generative cell is spindle-shaped, with microtubules organized in bundles and distributed in the cell cortex to form a basketlike structure beneath the generative-cell plasma membrane. During generative-cell migration through the pollen tube, the organization of the microtubule bundles changes following nuclear division. A typical metaphase plate is not usually formed. The generative-cell division is characterized by the extension of microtubules concomitant with a significant cell elongation. After karyokinesis, microtubule bundles reorganize to form a phragmoplast between the two sperm nuclei. The microtubule organization during generative-cell division inConvallaria majalis shows some similarities but also differences to that in other members of the Liliaceae.Abbreviations CLSM confocal laser scanning microscopy - EM electron microscopy - GC generative cell - GN generative nucleus - MT microtubule - SC sperm cell - SN sperm nucleus - VN vegetative nucleus     

Some events of mitosis and cytokinesis in the generative cell of Ornithogalum virens L.

The organization of the microtubule (Mt) cytoskeleton during mitosis and cytokinesis of the generative cell (GC) in Ornithogalum virens L. (bicellular pollen type, chromosome number, n = 3) from prophase to telophase/sperm formation was investigated by localization of -tubulin immunofluorescence using a conventional fluorescence microscope and a confocal laser scanning microscope. Chromosomes were visualized with DNA-binding fluorochrome dyes (ethidium bromide and 46-diamino-2-phenyl-indole). The GC of O. virens is characterized by G2/M transition within the pollen grain and not in the pollen tube as occurs in the majority of species with bicellular pollen. It was found that prophase in the GC starts before anthesis and prometaphase takes place after 10 min of pollen germination. The prophase Mts are organized into three prominent bundles, located near the generative nucleus. The number of these Mt bundles is the same as the number of GC chromosomes, a relation which has not previously been considered in other species. The most evident feature in the prophase/ prometaphase transition of O. virens GC is a direct rapid rearrangement of Mt bundles into a network which appears to interact with kinetochores and form a typical prometaphase Mt organization. The metaphase chromosomes are arranged into a conventional equatorial plate, and not in tandem as is thought to be characteristic of GC metaphase. The metaphase spindle consists of kinetochore fibres and a few interzonal fibres which form dispersed poles. Anaphase is characterized by a significant elongation of the mitotic spindle concomitant with the extension of the distance between the opposite poles. At anaphase the diffuse poles converge. Cytokinesis is realized by cell plate formation in the equatorial plane of the GC. The phragmoplast Mts between two future sperm nuclei appear after Mts of the mitotic spindle have disappeared.Abbreviations DAPI 46-diamino-2-phenyl-indole - GC generative cell - GN generative nucleus - Mt microtubule This research was made possible in part due to TEMPUS Programme and Global Network for Cell and Molecular Biology UNESCO grants to Magorzata Bana. The experimental part of the work was done in Siena University. M. Banas is very grateful to Prof. Mauro Cresti and his group for scientific interest, offering the excellent laboratory facilities, and kind reception.     

Ultrastructural features of Aloe ciliaris pollen

Summary Both the internal anatomy and the external morphology of the mature pollen grain of Aloe ciliaris have been studied, together with the cytological changes occurring during pollen activation. In mature pollen, the generative cell (GC) and the vegetative nucleus (VN) are closely associated with each other, and both can be found in the central part of the grain. In the generative cytoplasm, some organelles and microtubular bundles are present. In the vegetative cell, dictyosomes, stacks of rough endoplasmic reticulum, mitochondria, plastids, vacuoles, ribosomes, and masses of fibrillar material have been described. During pollen activation, important changes occur in both the generative and vegetative cells (VC). In the GC, the microtubular bundles become clearly visible, and the GC and VC gradually move towards the germ pore. The RER cisterns become free from the stacks, and organelles, such as dictyosomes, become very active. The fibrillar masses gradually decrease in number, and the individual fibrils become more evident and clearer in resolution.This research was carried out in the framework of contract no. BAP-0204-I of the Biotechnology Action Programme of the Commission of the European Communities     

The organization of the cytoskeleton in the generative cell and sperms ofHyacinthus orientalis

Summary The microtubular cytoskeleton of the generative cell (GC) ofHyacinthus orientalis has been studied until the formation of the sperm cells (SCs). Immunofluorescence procedures in combination with confocal laser scanning microscopy (CLSM) has enabled the visualization of the organization of the microtubular cytoskeleton. Chemical fixation and freeze-fixation electron microscopy have been used to investigate the cytoskeleton and the ultrastructural organization of the GC and SCs. During pollen activation the GC is spindle-shaped. Microtubules (MTs) are organized as bundles and distributed in proximity of the GC plasmamembrane, forming a basket-like structure. Following migration through the pollen tube, the basket-like structure becomes more intertwined. During the nuclear division the MTs are involved in the segregation of the chromosomes and kinetochores are clearly discernible. Association with organelles is also observed. The chromosomes of the GC remain condensed until they separate in two sperm nuclei. The pre-prophase band was never observed. At the end of the GC division the microtubular network reorganizes in the two SCs.Abbreviations CLSM confocal laser scanning microscopy - DAPI 46-diamidino-2-phenyl-indole - F-S freeze-substitution - GC generative cell - MT microtubule - PBS phosphate buffered saline - R-F rapid freeze-fixation - SC sperm cell - TBS tris buffered saline - VN vegetative nucleus     

Lily cofactor-independent phosphoglycerate mutase: purification, partial sequencing, and immunolocalization

A cofactor-independent phosphoglycerate mutase (PGAM-i) was isolated to homogeneity from monocotyledonous Lilium longiflorum Thunb. Two-dimensional (2D) polyacrylamide gel electrophoresis resolved three PGAM-i forms. This enzyme was originally identified by cross-reactivity to antibodies affinity-purified from 2D gels using human vitronectin (VN). Antibody produced against a denatured protein spot from a 2D gel did not recognize VN protein, but partial protein and DNA sequencing showed similarity of the former protein to maize PGAM-i. Immunoblots from roots, styles, leaves, and anthers showed the presence of PGAM-i in all tissues examined; it was isolated predominantly from the soluble cell fraction, with some present in the insoluble cell fraction. Immunoelectron microscopy demonstrated its localization in the cytoplasm and plastids in root cells near the apical meristem. In addition, immunogold labeling detected signals from the nucleus. The immunohistochemical localization of the enzyme in the nucleus, as well as in the cytosol and plastids, indicates that lily PGAM-i might have multiple functions in the cell.Abbreviations ELISA enzyme-linked immunosorbent assay - PGAM cofactor-dependent phosphoglycerate mutase - PGAM-i cofactor independent phosphoglycerate mutase - TEM transmission electron microscopy - 2D two dimensional - VN vitronectin     

Unequal distribution of plastids during generative cell formation in Impatiens

Summary This paper describes the unequal distribution of plastids in the developing microspores of Impatiens walleriana and Impatiens glandulifera which leads to the exclusion of plastids from the generative cell. During the development from young microspore to the onset of mitosis a change in the organization of the cytoplasm and distribution of organelles is gradually established. This includes the formation of vacuoles at the poles of the elongate-shaped microspores, the movement of the nucleus to a position near the microspore wall in the central part of the cell, and the accumulation of the plastids to a position near the wall at the opposite side of the cell. In Impatiens walleriana, the accumulated plastids are separated from each other by ER cisterns, and some mitochondria are also accumulated. In both Impatiens species, the portion of the microspore in which the generative cell will be formed is completely devoid of plastids at the time mitosis starts.     

Mechanisms for independent cytoplasmic inheritance of mitochondria and plastids in angiosperms

The inheritance of mitochondria and plastids in angiosperms has been categorized into three modes: maternal, biparental and paternal. Many mechanisms have been proposed for maternal inheritance, including: (1) physical exclusion of the organelle itself during pollen mitosis I (PMI); (2) elimination of the organelle by formation of enucleated cytoplasmic bodies (ECB); (3) autophagic degradation of organelles during male gametophyte development; (4) digestion of the organelle after fertilization; and (5)—the most likely possibility—digestion of organellar DNA in generative cells just after PMI. In detailed cytological observations, the presence or absence of mitochondrial and plastid DNA in generative cells corresponds to biparental/paternal inheritance or maternal inheritance of the respective organelle examined genetically. These improved cytological observations demonstrate that the replication or digestion of organellar DNA in young generative cells just after PMI is a critical point determining the mode of cytoplasmic inheritance. This review describes the independent control mechanisms in mitochondria and plastids that lead to differences in cytoplasmic inheritance in angiosperms.