Cellularization of the female gametophyte in Ranunculus sceleratus

1989 ◽  
Vol 67 (5) ◽  
pp. 1325-1330 ◽  
Author(s):  
N. N. Bhandari ◽  
P. Chitralekha
Keyword(s):  
Female Gametophyte ◽  
Horizontal Cell ◽  
Embryo Sac ◽  
Cell Plate ◽  
Mitotic Division ◽  
The Other ◽  
Central Vacuole ◽  
Distinct Cell ◽  
Antipodal Cells ◽  
Vertical Cell

Wall formation in Ranunculus sceleratus takes place simultaneously at the micropylar and chalazal poles of the embryo sac. During the last (third) mitotic division resulting in an eight-nucleate embryo sac, three distinct cell plates are formed at either pole. Of the three cell plates, CPI (horizontal), CPE (oblique), and CPIII (vertical), the first two are formed between the separating chromatin masses of the two dividing nuclei. CPIII (vertical cell plate) arises subsequently between the first two plates. CPI (horizontal cell plate) extends perpendicular to the long axis of the embryo sac to separate the central vacuole and one nucleus (polar) from the quartet of nuclei. The other two cell plates extend simultaneously between the three remaining nuclei; CPII (oblique plate) cuts off one of the nuclei while CPIII (vertical cell plate) separates the other two. Consequently, the egg apparatus, central cell with two polar nuclei, and three antipodal cells are formed.

Analysis of Nondisjunction Induced by the R-X1 Deficiency during Microsporogenesis in Zea Mays L.

Genetics ◽  
1988 ◽  
Vol 119 (4) ◽  
pp. 975-980
Author(s):  
Z Y Zhao ◽  
D F Weber
Keyword(s):  
Zea Mays L ◽  
Embryo Sac ◽  
Mitotic Division ◽  
The Other ◽  
Chromosome 6 ◽  
Nucleolar Organizing Region ◽  
Sperm Nuclei ◽  
Embryo Sac Formation ◽  
And Control ◽  
Generative Nuclei

Abstract The r-X1 deficiency in maize induces nondisjunction at the second mitotic division during embryo sac formation. However, it was not known if this deficiency also induces nondisjunction during the microspore divisions. Microsporogenesis in plants lacking or containing this deficiency was compared using two approaches. First, chromosome numbers were determined in generative nuclei. Many (8.3%) of the generative nuclei in r-X1-containing plants were aneuploid; however, those from control plants were all haploid. Thus, this deficiency induces nondisjunction during the first microspore division. Second, nucleoli were analyzed in microspores. The only nucleolar organizing region in maize is on chromosome 6. If chromosome 6 underwent nondisjunction during the first microspore division, one nucleus in binucleate microspores would contain no nucleolus and the other would contain two nucleoli (or one nucleolus if the nucleoli fused). Only one (0.03%) microspore of this type was observed in control plants while 1.12% were found in r-X1-containing plants. Thus, the r-X1 deficiency induces nondisjunction of chromosome 6 during the first microspore division. However, both of the sperm nuclei in trinucleate microspores contained one nucleolus in r-X1-containing and control plants; thus, this deficiency does not induce nondisjunction of chromosome 6 (and presumably other chromosomes) during the second microspore division.

scholarly journals Developmental, ultrastructural and cytochemical investigations of the female gametophyte in Sedum rupestre L. (Crassulaceae)

PROTOPLASMA ◽  
2020 ◽  
Author(s):  
Emilia Brzezicka ◽  
Małgorzata Kozieradzka-Kiszkurno
Keyword(s):  
Female Gametophyte ◽  
Current Knowledge ◽  
Embryo Sac ◽  
Main Function ◽  
Filiform Apparatus ◽  
Electron Dense Material ◽  
Reported Data ◽  
Functional Megaspore ◽  
Sedum Rupestre ◽  
Antipodal Cells

AbstractThis article describes the development of female gametophyte in Sedum rupestre L. New embryological information about the processes of megasporogenesis and megagametogenesis provided in this paper expand the current knowledge about the embryology of the studied species. S. rupestre is characterized by monosporic megasporogenesis and the formation of Polygonum–type embryo sac. The process of megasporogenesis is initiated by one megaspore mother cell, resulting in the formation of a triad of cells after meiosis and cytokinesis. The functional megaspore, which is located chalazally, is a mononuclear cell present next to the megaspore in the centre of the triad. Only one of the two non-functional cells of the triad is binucleate, which occur at the micropylar pole. In this paper, we explain the functional ultrastructure of the female gametophytic cells in S. rupestre. Initially, the cytoplasm of the gametophytic cells does not differ from each other; however, during differentiation, the cells reveal different morphologies. The antipodals and the synergids gradually become organelle-rich and metabolically active. The antipodal cells participate in the absorption and transport of nutrients from the nucellar cells towards the megagametophyte. Their ultrastructure shows the presence of plasmodesmata with electron-dense material, which is characteristic of Crassulaceae, and wall ingrowths in the outer walls. The ultrastructure of synergid cells is characterized by the presence of filiform apparatus and cytoplasm with active dictyosomes, abundant profiles of endoplasmic reticulum and numerous vesicles, which agrees with their main function—the secretion of pollen tube attractants. Reported data can be used to resolve the current taxonomic problems within the genus Sedum ser. Rupestria.

Embryo sac development in soybean: cellularization and egg apparatus expansion

1990 ◽  
Vol 68 (10) ◽  
pp. 2135-2147 ◽  
Author(s):  
M. W. Folsom ◽  
D. D. Cass
Keyword(s):  
Ultrastructural Study ◽  
Cell Walls ◽  
Embryo Sac ◽  
Chain Structure ◽  
Mitotic Division ◽  
The Other ◽  
Synergid Cell ◽  
Egg Apparatus ◽  
Embryo Sac Development

An ultrastructural study of soybean embryo sac development was performed. Prior to the final mitotic division and cellularization a nuclear rearrangement occurs that involves the chalazal movement of one of the two micropylar nuclei. During cellularization this nucleus divides to form the egg and micropylar polar nuclei and produces the wall that separates the central ceil from title space occupied by the egg apparatus. Within this space the other nucleus divides to form the two synergid nuclei and one of the two walls that separate the egg and synergid cells from one another. Egg apparatus cells are initially densely cytoplasmic, each is enclosed by thick, highly dissected walls, and they are all similar with respect to distribution of organelles except that synergid nuclei are micropylar to the egg nucleus. There is a progressive thinning and segmentation of egg apparatus walls during cellular expansion until they resemble the beaded chain structure seen in the mature egg and synergid cell walls. Taken as a whole these observations suggest that the chalazal movement of one of the two micropylar nuclei during the 4-nucleate stage is pivotal in determining future patterns of egg apparatus development.

Ovule and megagametophyte development in selected species of Apeibeae and Grewieae (Malvaceae–Grewioideae) from South America and its systematic implications

2016 ◽  
Vol 64 (5) ◽  
pp. 369
Author(s):  
Elsa Lattar ◽  
Beatriz Gloria Galati ◽  
María Silvia Ferrucci
Keyword(s):  
Female Gametophyte ◽  
Mixed Type ◽  
Outer Integument ◽  
The Other ◽  
Filiform Apparatus ◽  
Polygonum Type ◽  
Chalazal Megaspore ◽  
The Family ◽  
Female Gametophyte Development ◽  
Antipodal Cells

This is the first embryological report of the Grewioideae subfamily, which is meant to contribute to the characterisation of the genera Corchorus, Luehea and Triumfetta. Ovule and female gametophyte development in C. argutus, L. divaricata and T. semitriloba was analysed. The ovules of all species are anatropous, bitegmic and of crassinucellate mixed type. The micropyle of the studied species is formed by the outer integument (exostome). The ovule of L. divaricata differs from those of the other two species because the chalazal tissue expands forming a cap, which gives rise to a wing in the seed. All species present one hypostase. The megaspore mother cell gives rise to a linear megaspore triad in C. argutus and L. divaricata, whereas in T. semitriloba, triads and diads can be observed in the same ovule. The chalazal megaspore develops a seven-celled and eight-nucleate female gametophyte corresponding to the Polygonum type. The synergids of L. divaricata have hooks and a conspicuous filiform apparatus. The antipodal cells in C. argutus are persistent, whereas in the other species, they are small and ephemeral. The embryological characters are compared with those of other taxa within the family and the megagametophyte formation in these species is discussed.

Occurrence of Giant Antipodals in the Female Gametophytes of Australian Bossiaeeae, Indigofereae and Mirbelieae (Leguminosae)

1990 ◽  
Vol 38 (4) ◽  
pp. 395 ◽  
Author(s):  
BG Cameron ◽  
N Prakash
Keyword(s):  
Female Gametophyte ◽  
The Other ◽  
Taxonomic Significance ◽  
Gametophyte Development ◽  
Australian Species ◽  
Female Gametophyte Development ◽  
Antipodal Cells

A survey of the female gametophyte development in 62 Australian species of subfamily Papilionoideae showed that giant antipodal cells were found in all species of Bossiaea, Goodia and Platylobium of the tribe Bossiaeeae; in all species of Burtonia, Daviesia, Gompholobium, Sphaerolobium and Viminaria of the tribe Mirbelieae; and in Indigofera australis of the tribe Indigofereae. The giant antipodals were deeply staining, usually had large nuclei with prominent nucleoli and persisted well after fertilisation. The giant antipodals appeared to have a nutritive function in the female gametophyte as they develop at the expense of the nucellus. The occurrence of giant antipodals is of taxonomic significance in the tribes Mirbelieae and Bossiaeeae. This evidence supports the separation of the 'Templetonia group' (Templetonia, Hovea, Lamprolobium) from the other genera in the Bossiaeeae (Bossiaea, Goodia and Platylobiurn or the 'Bossiaea group'). The suggestion is also made to reassess the relationships and composition of the tribes Mirbelieae and Bossiaeeae based on the presence of giant antipodal cells. This would result in the tribe Bossiaeeae consisting of the genera Burtonia, Daviesia, Gompholobium, Sphaerolobium and Viminaria and the members of the 'Bossiaea group', Bossiaea, Goodia and Platylobium.

THE CAUSE OF INCOMPATIBILITY BETWEEN BARLEY AND RYE

1945 ◽  
Vol 23c (1) ◽  
pp. 1-15 ◽  
Author(s):  
W. P. Thompson ◽  
Dorothy Johnston
Keyword(s):  
Early Stage ◽  
Embryo Sac ◽  
The Other ◽  
Abnormal Development ◽  
Barley Embryo ◽  
The Third ◽  
Other Hand ◽  
Hybrid Embryo ◽  
Viable Seeds ◽  
Antipodal Cells

When common barley is pollinated by common rye fertilization takes place normally but no viable seeds are produced. The immediate cause of the failure is abnormal development of the hybrid endosperm and particularly of the endospermic nuclei, which from an early stage are of immense size and are always few in number. No cells are ever formed in the endosperm. It collapses on the fifth or sixth day after pollination and disintegrates. The hybrid embryo, on the other hand, although it grows more slowly than the pure barley embryo from the third day, remains normal and healthy in appearance long after the endosperm has become very abnormal or has completely collapsed. The behaviour of the maternal tissues of crossed material is similar to that of selfed material, and rules out the theory of somatoplastic incompatibility. The behaviour of the antipodal cells of the embryo sac is not sufficiently different from normal to be of significance.

Some aspects of the life history of Callistemon citrinus (Curt.) Skeels

1969 ◽  
Vol 17 (1) ◽  
pp. 107 ◽  
Author(s):  
N Prakash
Keyword(s):  
Life History ◽  
Female Gametophyte ◽  
Embryo Sac ◽  
Basic Type ◽  
Cultivated Plants ◽  
Anther Wall ◽  
Polygonum Type ◽  
Native Populations ◽  
History Of ◽  
Antipodal Cells

Pollen development is irregular in native populations but regular in the cultivated plants investigated. Development of the anther wall is of the Basic type and the tetrasporangiate anthers shed their pollen at the two-celled stage through longitudinal slits. The single vascular bundle of each stamen gives off two traces in the connective. The ovules are anatropous, crassinucellar, and bitegmic. The swollen distal ends of both integuments form the micropyle. The single archesporial cell cuts off a parietal cell, and during megasporogenesis a one- to three-layered parietal tissue is formed which collapses during the development of the embryo sac. Occasionally the megaspore mother cell degenerates but in these instances the growth of the ovule is unimpaired. The female gametophyte follows the Polygonum type of development, and when mature is eight-nucleate and includes three ephemeral antipodal cells. Some abnormalities pertaining to the number and arrangement of nuclei in the embryo sac have been observed and hardly 4% of the ovules form fertile seeds. The seed coat is formed from both the integuments. A hypostase is differentiated in the seed.

scholarly journals The mac1 Gene: Controlling the Commitment to the Meiotic Pathway in Maize

Genetics ◽  
1996 ◽  
Vol 142 (3) ◽  
pp. 1009-1020 ◽  
Author(s):  
William F Sheridan ◽  
Nadezhda A Avalkina ◽  
Ivan I Shamrov ◽  
Tatyana B Batyea ◽  
Inna N Golubovskaya
Keyword(s):  
Female Gametophyte ◽  
Embryo Sac ◽  
Flowering Plants ◽  
Normal Female ◽  
Ovule Development ◽  
Partial Sterility ◽  
Embryo Sac Formation ◽  
Female Gametophyte Development ◽  
Normal Meiosis ◽  
Pleiotropic Mutation

Abstract The switch from the vegetative to the reproductive pathway of development in flowering plants requires the commitment of the subepidermal cells of the ovules and anthers to enter the meiotic pathway. These cells, the hypodermal cells, either directly or indirectly form the archesporial cells that, in turn, differentiate into the megasporocytes and microsporocytes. We have isolated a recessive pleiotropic mutation that we have termed multiple archesporial cells1 (macl) and located it to the short arm of chromosome 10. Its cytological phenotype suggests that this locus plays an important role in the switch of the hypodermal cells from the vegetative to the meiotic (sporogenous) pathway in maize ovules. During normal ovule development in maize, only a single hypodermal cell develops into an archesporial cell and this differentiates into the single megasporocyte. In macl mutant ovules several hypodermal cells develop into archesporial cells, and the resulting megasporocytes undergo a normal meiosis. More than one megaspore survives in the tetrad and more than one embryo sac is formed in each ovule. Ears on mutant plants show partial sterility resulting from abnormalities in megaspore differentiation and embryo sac formation. The sporophytic expression of this gene is therefore also important for normal female gametophyte development.

The Structure of Sycamore Callus Cells During Division in a Partially Synchronized Suspension Culture

1970 ◽  
Vol 6 (2) ◽  
pp. 299-321
Author(s):  
K. ROBERTS ◽  
D. H. NORTHCOTE
Keyword(s):  
Cell Wall ◽  
Electron Microscope ◽  
Cell Plate ◽  
Optical Microscope ◽  
The Other ◽  
Active Movement ◽  
Developmental Sequence ◽  
Golgi Bodies ◽  
Dividing Cells ◽  
Peripheral Cytoplasm

Sycamore suspension callus cells have been partially synchronized to give a culture with a mitotic index of 15%. Living dividing cells of the culture have been examined with Nomarski differential interference optics and a comparable study made on fixed cells with the electron microscope. An organized band of reticulate cytoplasm partially encircles the nucleus at mitosis. The cell divides by the formation of a phragmosome which grows across the large vacuole; this allows the organization of the cytoplasm which forms the cell plate to be examined separately from the more general cytoplasm of the cell. The cell plate grows from one side of the cell to the other and down its length a complete developmental sequence can be seen. The Golgi bodies and the endoplasmic reticulum are probably involved in the formation of material for the construction of the cell plate and young cell wall. Microfibrils are formed within the plate in the more mature regions, while material contained within vesicles is incorporated at the young growing edge. At the edge of the plate microtubules are found and these correspond to the fibrillar appearance of the phragmoplast seen with the optical microscope. In the living cell an active movement of organelles along the peripheral cytoplasm can be seen and with fixed cells viewed with the electron microscope microtubules are often found adjacent to the plasmalemma and lying close to mitochondria, crystal-containing bodies and plastids. The appearance of crystal-containing bodies and plastids containing phytoferritin is described.

3H-adenosine uptake selectively labels rod horizontal cells in goldfish retina

1997 ◽  
Vol 14 (2) ◽  
pp. 207-212 ◽  
Author(s):  
Keith M. Studholme ◽  
Stephen Yazulla
Keyword(s):  
Staining Pattern ◽  
Outer Nuclear Layer ◽  
Horizontal Cell ◽  
Horizontal Cells ◽  
The Other ◽  
Axon Terminals ◽  
Adenosine Uptake ◽  
Double Label ◽  
Injection Methods ◽  
Goldfish Retina

AbstractThere are four types of horizontal cell in the goldfish retina, three cone- and one rod-type. The neurotransmitter of only one type, the H1 (cone) horizontal cell, has been identified as GABA. 3H-adenosine uptake was examined as a possible marker for the other classes of horizontal cell. Isolated goldfish retinae were incubated in 3H-adenosine (10–40 μCi) in HEPES-buffered saline for 30 min, then fixed, embedded in plastic, and processed for light-microscopic autoradiography (ARG). For double-label immuno/ARG studies, l-μm-thick sections were processed for GABA postembed immunocytochemistry, then for ARG. 3H-adenosine uptake was localized to cone photoreceptors, presumed precursor cells in the proximal outer nuclear layer, and to a single, continuous row of horizontal cell bodies in the inner nuclear layer. No uptake was localized to the region of horizontal cell axon terminals. 3H-adenosine uptake did not colocalize with GABA-IR in H1 horizontal cells, but it did colocalize with adenosine deaminase immunoreactivity. It is concluded that 3H-adenosine uptake selectively labels rod horizontal cells in the goldfish retina based on position and staining pattern, which are similar to rod horizontal cells stained by Golgi or HRP injection methods. The use of 3H-adenosine uptake may provide a useful tool to study other properties of rod horizontal cells (i.e. development) as well as provide clues as to the transmitter used by these interneurons.

Sign in / Sign up

Export Citation Format

Share Document