Novel sporophyte-like plants are regenerated from protoplasts fused between sporophytic and gametophytic protoplasts of<Emphasis Type="Italic"> Bryopsis plumosa</Emphasis>

Protoplasts of the marine coenocytic macrophyte Bryopsis plumosa (Hudson) C. Agardh. [Caulerpales] can easily be obtained by cutting gametophytes or sporophytes with sharp scissors. When a protoplast isolated from a gametophyte was fused with a protoplast isolated from a sporophyte of this alga, it germinated and developed into either one of two completely different forms. One plant form, named Type G, appeared quite similar to a gametophyte, and the other, named Type S, looked similar to a sporophyte. While the Type G plant contained many small nuclei of gametophyte origin together with a single giant nucleus of sporophyte origin, the Type S plant contained many large nuclei of uniform size. These large nuclei in the Type S plant had metamorphosed from the gametophytic nuclei, and were not formed through division of the giant nucleus of sporophyte origin. Fragments of the Type S plant, each having such a large nucleus, developed into creeping filaments that look very similar to sporophytes. While cell walls of gametophytes and Type G plants were stained by Congo-red, those of the thalli of regenerated Type S plants and sporophytes were not stained by the dye. This indicated that the large nuclei of the Type S plant did not express genes for xylan synthesis, which are characteristic of gametophytes. Two-dimensional gel electrophoretic analysis revealed that most of the proteins synthesized in the Type S plant were identical to those of sporophytes. These results strongly suggest that in the Type S plant, the gametophytic nuclei are transformed into sporophyte-like nuclei by an unknown factor(s) produced by the giant nucleus of sporophyte origin and that the transformed nuclei express the set of genes characteristic of sporophytes. Despite morphological similarity, however, the regenerated Type S plant could not produce zoospores, because its large nuclei did not divide normally. The transformed large nuclei of gametophyte origin still seemed to be in the haploid state.Abbreviations DAPI 4,6-Diamidino-2-phenylindole - DIC Differential interference contrast - IEF Isoelectric focusing - PES Provasolis enriched seawater     

Behavior of nuclei during zoosporogenesis in Bryopsis plumosa (Bryopsidales, Chlorophyta)

The behavior of nuclei during zoosporogenesis in Bryopsis plumosa (Bryopsidales, Chlorophyta) was examined by fluorescence and electron microscopy. Each mature filamentous sporophyte had a single lenticular nucleus, which was about 25 m in diameter and embedded in a thick cytoplasmic layer. At the commencement of multinucleation, giant nuclei with large vacuolated nucleoli, giant nuclei containing chromosomes, and dumbbell-shaped nuclei were observed. Sometimes, two small nuclei also appeared in the thick cytoplasm where the giant nucleus had presumably been present. Electron microscopy revealed the existence of ribbon-like structures resembling synaptonemal complexes within the nucleus having a large vacuolated nucleolus. Nuclei extended their distribution by repetitive divisions. A pair of centrioles was adjacent to the interphase nucleus. When the nuclei were distributed throughout the cell, they became localized nearly equidistantly from one another, each being surrounded by several chloroplasts. At this stage, many centrioles lay along the nuclear surface. The bulk of cytoplasm was then divided into many masses of protoplasm, each of which developed into a uninucleate, stephanokontic zoospore with a whorl of flagella.     

Chromosome behavior in the primary nucleus ofAcetabularia calyculus as revealed by epifluorescent microscopy

Summary Chromosome behavior preceding secondary nuclei formation within a giant primary nucleus (50–100 m in diameter) inAcetabularia calyculus was observed by the fluorescence emitted from 4-6-diamidino-2-phenylindole (DAPI)-stained DNA.Throughout the period when the large nucleolus was present in the primary nucleus, thin chromonemata were observed twining around the nucleolus. Nuclear division was initiated by degeneration of the sausage-shaped nucleolus into a number of spherical subunits soon after the initiation of cap formation. On the fourth day of cap development, the chromonemata became thicker and chromomeres appeared. They accumulated adjacent to the single spherical nucleolus. The lump of chromosomes became loosened and thick chromosomes were scattered in the nucleus. The peculiar shapes of chromosomes which suggest the existence of chiasmata were frequently observed until the chromosome segregation started. This sequence of chromosome behavior seems to be the prophase of meiotic division. Chromosome segregation, the first meiotic division, occurred on the seventh day of cap development, probably being accompanied by the second meiotic division. Immediately after nuclear division of the primary nucleus, secondary nuclei were formed and cyst formation started 24 hours after repeated mitoses of the secondary nuclei.     

Factors Mediating the Vitamin B12 Requirement of Euglena

SYNOPSIS. Deprived of vitamin B₁₂, Euglena gracilis strain Z ceases to divide which we believe to be a function of the light regime: division inhibition occurs more quickly in continuous light than in alternating (6L : 6D) light and not at all in total darkness. This phenomenon is dependent on the carbon source; cells grown in glutamate-malate medium do not divide regardless of the culture conditions while dl -lactate as carbon source permits growth in darkness in the absence of B₁₂. Conditions which lead to an increased O₂ or decreased CO₂ tension in the medium, such as agitation in darkness or incubation in red or white light, result in inhibition of division. This inhibition can be reversed by re-transferring the cells to still culture in the dark or, in the case of light-induced blockage, by the addition of DCMU.     

Nuclear behavior during branch formation in a centrifugedAdiantum protonema and the nuclear polarity

A new branch was induced on the side wall of fern protonema by cell centrifugation and subsequent polarized red light irradiation after the induction of cell division under white light. Nuclear behavior during the branch formation was analyzed. Immediately after cell division, the two daughter nuclei moved away from the division site in both red and dark conditions. Under continuous irradiation with polarized red light, cell swelling occurred as an early step of branching near the cell dividing wall, even though the nucleus was localized far from the branching site at the beginning of the swelling. After a new branch started to grow, the nucleus returned to the branching site and moved into the new branch from its basipetal end. When a protonema incubated in the dark was centrifuged again acropetally or basipetally just before the irradiation of polarized red light, the rate of apical growth or branch formation was increased, respectively. Moreover, growth of a branched protonema was altered from its former apex or from the branch again by dislocating the nucleus acropetally or basipetally by centrifugation, respectively. These facts suggest that the nucleus has no polarity physiologically, i.e. head and tail, namely either end of the spindle-shaped nucleus can be the nuclear front in a tip-growing protonema.     

Light germination ofAnthoceros miyabeanus spores

The effects of light on the spore germination of a hornwort species,Anthoceros miyabeanus Steph., were investigated. Spores of this species were photoblastic, but their sensitivities to light quality were different. Under either continuous white, red or diffused daylight, more than 80% of the spores germinated, but under blue light none or a few of them germinated. Under continuous far-red light or in total darkness, the spores did not germinate at all.Anthoceros spores required red light irradiation for a very long duration, i.e., over 12–24 hr of red light for saturated germination. However, the spore germination showed clear photo-reversibility by repeated irradiation of red and far-red light. The germination pattern clearly varied with the light quality. There were two fundamental patterns; (1) cell mass type in white or blue light: spores divide before germination, and the sporelings divide frequently and form 1–2 rhizoids soon after germination, and (2) germ tube type in red light: spores germinate without cell division, and the single-cell sporelings elongate without cell division and rhizoid formation.     

Visualization of cytoskeletal changes through the life cycle inAcetabularia

Summary The cytoskeleton in the siphonous, marine green algaAcetabularia is visualized by immunocytochemistry using antibodies against plant alfa tubulin and animal smooth muscle actin. In the vegetative phase of the life cycle, when the cell grows a cylindrical stalk and until the reproductive cap is completed, actin forms continuous, parallel bundles that extend through the entire length of the stalk and cap rays respectively. Microtubules (MTs) cannot be detected until the primary nucleus, located in the rhizoid of the giant cell, divides to form thousands of secondary nuclei. MTs can then be seen radiating from each secondary nucleus that is encountered in the stalk on its migration upwards into the cap rays. They are oriented mostly parallel to the long axis of the cell. At arrival in the cap rays up to the white spot stage, when nuclei assume equidistant positions in the cap ray cytoplasm, a radiating system of MTs forms around each nucleus and dramatically increases until impressive radial arrays have developed. This phase coincides with a disappearance of actin bundles in the cap rays, but they are retained in the stalk cytoplasm. Shortly after that additional MTs appear around the disk like partitions of cap ray cytoplasm. Concomitantly, bundles of actin reappear colinearly with the circumferrential MTs eventually forming complete rings around each disk of cap ray cytoplasm. During this process the compartments of the future cysts are gradually bulging outwards and simultaneously the rings of actin sink inwards until domes are formed with the nuclei fixed in the top centers of the domes. At this stage the peripheral areas of the radiating MT systems around the nuclei start to break down, whereas the circumferrential MT systems remain intact. Subsequently, the rings of both actin and MTs decrease in diameter, and finally contract to a spot opposite the nucleus, while the cysts continue to develop their oval shape. After the cysts have become separated, they round up and enter several rounds of nuclear divisions. MTs form short radial arrays around each nucleus with minor changes due to a reduction of MTs during division followed by a reappearance after completion of each division. Actin is rearranged in the cysts to a cortical network of randomly oriented, short bundles, that is maintained until gamete formation sets in.These findings accentuate the involvement of Cytoskeletal elements in the key steps of morphogenesis inAcetabularia to an extent that is unknown in higher plants.     

Distribution of chromosome material during division of giant nuclei by fragmentation in rodent trophoblast. Morphologic and cytophotometric study]

A study was made of a population of secondary giant cells (in the placenta of white rats and mice), of which a rather high polyploidy (128c--1024c) is characteristic, and which remains viable up to the end of pregnancy. At a certain stage of cell differentiation, some giant nuclei, looking as interphase nuclei, are divided into numerous smaller nuclear fragments bound with nuclear membranes. Two ways of division have been described: by a progressive budding of small nuclei into the cytoplasm, and the total division of the original nucleus into numerous tightly contracting nuclear fragments. Multinuclear cells originating from the nuclear fragmentation rather soon degenerate. The cytophotometrical measurement of the DNA amount in newly formed fragments has shown their ploidy extending from 1 to 32c, di-, three-, tetra-, and octoploid nuclei predominating. The distribution of chromosomal markers of the interphase nuclei (nucleoli, heterochromatinous blocks of nucleolus-forming chromosomes) confirms the photometrical evidence on the trends of chromosome fragmentation into genes. The fragmentation of the giant nucleus is preceded by a complex rearrangement of genetical material in the original nucleus, resulting in becoming polygenomal from polytene, with individual genomes separating to be segregated again, during division.     

Requirements for division of the generative nucleus in cultured pollen tubes ofNicotiana

Summary Production of sperm cells by division of the generative cell occurs during growth ofNicotiana (tobacco) pollen tubes through the sporophytic tissue of the style, and is associated with transition to the second phase of pollen-tube growth. WhenNicotiana pollen tubes are grown in liquid culture, the extent of generative-nucleus division and the timing of this division depend on the chemical composition of the medium. Addition of reduced forms of nitrogen, either as mixed amino-acids (0.03% w/v of an acid hydrolysate of casein) or as 1 mM ammonium chloride, induces division of the generative nucleus in over 90% of the tubes; 3 mM calcium nitrate does not stimulate division. Individual amino-acids differ in their ability to induce this division. Contaminants in some batches of poly(ethylene glycol), which is a major component of pollen-tube growth media, inhibit generative-nucleus division; this inhibition is greater in the absence of nitrogen, which increases the observed nitrogen-dependence of division. Reduced forms of nitrogen are also required for growth of pollen tubes after division, when callose plugs are deposited. In the absence of nitrogen, growth continues until the point where sperm cell production would normally occur, then ceases. Addition of amino-acids or ammonium chloride thus allows cultured pollen tubes ofNicotiana to progress to their second phase of growth. WhenNicotiana pollen is germinated in a complete culture medium at 25–26°C, sperm nuclei are first observed in the growing tubes after about 10 h, and by about 16 h most of the tubes have undergone division; at lower temperatures, division is delayed. The timing of division also varies between species ofNicotiana, but division occurs similarly in self-compatible and self-incompatible species. Anaphase in an individual pollen tube is calculated to take less than 4 min. The resultant sperm nuclei usually trail behind the vegetative nucleus, but a variety of arrangements of the three nuclei are observed.Abbreviations DAPI 4,6-diamidino-2-phenylindole - PEG poly(ethylene glycol) - OG ordinary grade of PEG - SP Specially Purified for Biochemistry grade of PEG     

Stomatal neighbor cell polarity and division in <Emphasis Type="Italic">Arabidopsis</Emphasis>

Asymmetric divisions are key to regulating the number and patterning of stomata in Arabidopsis thaliana (L.) Heynh. Many formative asymmetric divisions take place in neighbor cells (NCs), cells adjacent to a stoma or stomatal precursor. TOO MANY MOUTHS is a receptor-like protein required for the correct plane of NC division, resulting in the placement of the new precursor distal to the pre-existing stoma. Because plant cells usually become polarized before asymmetric division, we studied whether NCs display a cytological asymmetry as a function of cell stage and of possible division behavior. Cells that divided in the developing leaf epidermis were smaller than 400 micro m(-2) in area and included NCs as well as isolated cells. All NCs in the youngest complexes divided with comparable frequencies, but divisions became restricted to the smaller and most recently produced NCs as the stomatal complex matured. The majority of developing NCs had distally located nuclei, suggesting that nuclear position is actively regulated in NCs. NC stages exhibiting distally located nuclei were the likeliest to divide asymmetrically. However, a distal nucleus did not necessarily predict an asymmetric division, because more NCs had distal nuclei than were likely to divide. No defect was detected in nuclear distribution in tmm NCs. These data suggest that TMM uses intercellular signals to control the plane of asymmetric division after or independently of nuclear positioning.     

Mitosis and mitotic wave propagation in the coenocytic alga,<Emphasis Type="Italic"> Vaucheria terrestris</Emphasis> sensu Goetz

Mitosis and cytoplasmic microtubule (MT) dynamics were observed for the first time in Vaucheria terrestris sensu Goetz. Mitosis could occasionally be seen in part of the cylindrical coenocytic cell. The frequency of encountering cells with dividing nuclei was highest (ca 12%) 4 h after the onset of light in 12 h light/12 h dark regimes; it decreased thereafter and approached zero during the dark period. From the anterior end of every interphase nucleus a unique, long MT bundle extended. Differential-interference optics reveals that there is a filamentous structure in front of the moving nucleus. In prophase, the interphase bundle disappeared and shorter MT bundles emanated from both ends of the nucleus. In metaphase, the cytoplasmic MTs completely disappeared, probably being recycled to spindles. Continuous MTs elongated in anaphase and developed into an interzonal spindle in telophase; this elongated up to as much as 10 m. The daughter nuclei were pushed away from each other by the interzonal spindle. Mitosis started synchronously in a relatively narrow region, and the mitotic stage propagated as a mitotic wave to adjacent regions, most frequently from tip to base. The role of the mitotic wave in tip growth and morphogenesis of a coenocytic cell is discussed.This paper is dedicated to the memory of Dr. Eiji Kamitsubo who passed away on 25 April 2003.     

Giant mitochondria in the mature egg cell ofPelargonium zonale

Summary Giant mitochondrial nuclei (known as nucleoids or mt-nuclei), which contain extremely large amounts of DNA, were studied in thin sections of the mature egg and proembryo (2 and 6 days after double fertilization) ofPelargonium zonale. Samples were embedded in Technovit 7100 resin, stained with 4,6-diamidino-2-phenylindole (DAPI) and examined by immuno-gold electron microscopic cytochemistry. The egg cell contained giant mitochondria (either long and stretched or cup-shaped) which contained a large amount of DNA (more than 4 megabase pairs). However, the other cells, such as synergids, the central cell and nucellus contained small spherical mitochondria. Giant mitochondria in the egg cell were often found to make mitochondria complexes due to the grouping of cupule-shaped mitochondria. Immuno-gold electron microscopic cytochemistry revealed that the mitochondrial DNA is localized in the electron transparent of the giant mitochondria. Apparently, the large mitochondria in the egg cell divided in stages to form small, spherical mitochondria during the early stages of embryogenesis and the DNA content in individual large mitochondrion also decreased significantly. The amount of mitochondrial DNA reached approximately 800 kbp in the globular embryo 6 days after double fertilization. The formation of giant mitochondria in mature eggs has significant aspects after double fertilization.     

Use of enlarged cells and nuclei for studying mitosis inNeurospora

Summary Mitotic division stages studied by light microscopy in differentNeurospora crassa cell types clearly resemble prophase, metaphase, anaphase, and telophase stages of higher eukaryotes. 1. When conidia are cultured in liquid medium containing 3.22 M ethylene glycol, they grow without cell division, forming giant spheres with multiple nuclei. In a few giant cells, nuclear numbers remain small (1 to 3) but the nuclei become very large. Seven large chromosomes are seen in some nuclei suggesting polyteny, 14 or more chromosomes are seen in other, very large nuclei, indicating polyploidy. Cell volume and nuclear volume are positively correlated in giant cells. Nuclear divisions are not synchronous within individual multinucleate giant cells. 2. Nuclear division stages were also observed in crosses heterozygous for the dominant mutant banana where haploid prefusion nuclei in late-forming croziers revert to mitosis. Swollen ascogenous hyphae become highly multinucleate after several rounds of mitosis. Mitosis is completely synchronous in nuclei of the same crozier cyst, providing replicate information for unambiguous identification of division stage. 3. Observations are also reported of mitosis in a cell-wall deficient slime strain. Previous observations on mitosis in large nuclei of the ascus are summarized for comparison. The nucleolus persists throughout mitosis in the giant cells, multinucleate reverted croziers, and in the cell-wall deficient slime strain. It is expelled from the dividing nuclei in the ascus. Spindles and spindle pole bodies, which are normally conspicuous in asci, are also seen in normal and reverted croziers, but they have not been clearly identified in the ethylene glycol-induced giant cells.     

Circadian rhythms in Kalanchoë: effects of irradiance and temperature on gas exchange and carbon metabolism

Gas exchange in K. blossfeldiana shows a circadian rhythm in net CO₂ uptake and transpiration when measured under low and medium irradiances. The period length varies between 21.4 h at 60 W m^-2 and 24.0 h at 10 W m^-2. In bright light (80 W m^-2) or darkness there are no rhythms. High leaf temperatures result in a fast dampening of the CO₂-uptake rhythm at moderate irradiances, but low leaf temperatures can not overcome the dampening in bright light. The rhythm in CO₂ uptake is accompanied by a less pronounced and more rapidly damped rhythm in transpiration and by oscillations in malate levels with the amplitude being highly reduced. The oscillations in starch content, usually observed to oscillate inversely to the acidification in light-dark cycles, disappear after the first cycle in continuous light. The balance between starch and malate levels depends in continuous light on the irradiance applied. Leaves show high malate and low starch content at low irradiance and high starch and low malate in bright light. During the first 12 h in continuous light replacing the usual dark period, malate synthesis decreases with the increasing irradiance. Up to 50 W m^-2 starch content decreases; at higher irradiances it increases above the values usually measured at the end of the light period of the 12:12 h light-dark cycle.Abbreviations CAM Crassulacean acid metabolism - FW fresh weight - PEP phosphoenolpyruvate     

Effects of narrow-beam irradiations with blue and far-red light on the timing of cell division in Adiantum gametophytes

Protonemata of the fern Adiantum capillusveneris L., grown as single-cell filaments under continuous red light, were irradiated with a narrow beam of blue light. Only irradiation of the region containing the nucleus induced cell division. Beams of 30 m in width, which corresponds to the diameter of the nucleus, or wider, were equally effective; beams 10 m wide or less were less effective. The results indicate that the nuclear region is the site of the blue- and near ultraviolet-light-absorbing pigment (P_B-NUV) which mediates the timing effect of cell division. In contrast, the effect of a narrow beam of far-red (FR) light, which delays the onset of the blue-light-induced cell division, was found to be present along the entire length of the protonema cell, including the largely vacuolated basal region of the latter. Polarized FR light having the electrical vector parallel to the protonema axis was less effective than that vibrating in other directions. These observations support the hypothesis that the phytochrome controlling the timing effect is localized in the plasma membrane.     

Nuclear protein matrix of giant nuclei of polythene chromosome organization of midge <Emphasis Type="Italic">Chironomus plumosus</Emphasis> determinates

Giant nuclei from salivary glands of the midge Chironomus plumosus were treated in situ with 2M NaCl detergent and nucleases to reveal residual nuclear matrix proteins (NMP). It was shown that, after the prestabilization of nonhistone proteins with 2 mM CuCl₂, the polythene chromosome body preserved its morphologic integrity and banding pattern, even after the extraction of all histones and DNA. The stabilized NPM of polythene chromosomes can be observed in both light and electron microscopy; no interchromatin fibrillary-granular structures are revealed in the nucleus except for peripheral lamina. Using the immunocytochemical method, in polythene chromosomes, we managed to detect major nonhistone proteins (topoisomerase IIα and SMC 1) and some RNA-components. Besides, in giant nuclei of larvae of early stages there is observed BrDU incorporation visualizing sites of DNA synthesis, which also are connected with NPM of polythene chromosomes. Thus, it can be concluded that structure of NPM of giant nuclei of Chironomus plumosus has all properties of NPMs of usual interphase nuclei; furthermore, this NPM determines specific structure of the polythene chromosome.     

Cytoskeleton reorganization,a key process in root-knot nematode-induced giant cell ontogenesis

Root-knot nematodes are plant parasitic worms that establish and maintain an intimate relationship with their host plants. RKN induce the redifferentiation of root cells into multinucleate and hypertrophied giant cells essential for nematode growth and reproduction. Major rearrangements of the cytoskeleton occur during giant cell formation. We characterized the first plant candidate genes implicated in giant cell actin and microtubule cytoskeleton reorganization. We showed previously that formins may regulate giant cell isotropic growth by controlling the assembly of actin cables. Recently we demonstrated that a Microtubule-Associated Protein, MAP65-3, is essential for giant cell development. In the absence of functional MAP65-3, giant cells started to develop but failed to fully differentiate and were eventually destroyed. In developing giant cells, MAP65-3 was associated with a novel kind of cell plate—the giant cell mini cell plate—that separates daughter nuclei. Despite karyokinesis occurs without cell division in giant cell, we demonstrated that cytokinesis is initiated and required for successful pathogen growth and development.Key words: cytoskeleton, microfilament, formin, microtubule, microtubule-associated protein, giant cells, nematodeRoot-knot nematodes (RKN) Meloidogyne spp. is one of the most damaging plant pathogen worldwide.¹ Their potential host range encompasses more than 2,000 plant species. During a compatible interaction, these obligate biotrophic pathogen have evolved an ability to manipulate host functions to their own benefit.^2–6 At the onset of parasitism, the infective second stage juveniles (J2) penetrate the root tip and migrate intercellularly to reach the root vascular cylinder. Each J2 then induces the redifferentiation of five to seven parenchymatic root cells into hypertrophied and multinucleate cells, named giant cells. Giant cells result from synchronous repeated karyokinesis without cell division.⁷ Despite lack of complete cytokinesis, we demonstrated that cytokinesis is initiated and essential for giant cell ontogenesis.⁸ Fully differentiated giant cells reach a final size about four hundred times that of root vascular cells and contain more than a hundred polyploid nuclei. Giant cell nuclei show an increase in DNA, possibly reflecting endoreduplication.⁹ These “feeding” giant cells constitute the exclusive source of nutrients for the nematode until reproduction. Giant cell development is accompanied by division and hypertrophy of surrounding cells, leading to a typical root gall formation, the primary visible symptom of infection.     

Giant Cells of Escherichia coli: a Morphological Study

Bacterial growth without division was observed in a giant cell-producing strain of Escherichia coli K-12. Giant cell production is controlled by the lon(-) (failure of cell division after irradiation) and mon(-) (formation of irregularly shaped cells) genes. Irradiation of a lon(-)mon(-) strain (P678-A(4)) with low doses of ultraviolet or ionizing radiation results in the production of large, amorphous giant cells with 500 to 1,000 times the volume of the nonirradiated parents. The concentration of NaCl in the growth medium was found to influence irradiated-cell morphology. Low concentrations (0.2% NaCl) resulted in elongated cells, whereas spherical giant cells were produced in the presence of high salt (1% NaCl) concentrations.Thin-section electron microscopy revealed an extensive network of intracellular membranes forming vacuoles, vesicles, and cisternae. These structures bear a striking resemblance to the rough and smooth membranes (endoplasmic reticulum, Golgi complex, vacuoles, etc.) found in eucaryotic cells.     

EMBRYOLOGY OF CALYPSO BULBOSA. I. OVULE DEVELOPMENT

Calypso bulbosa is a terrestrial orchid that grows in north temperate regions. Like many orchids, the Calypso has ovules that are not fully developed at anthesis. After pollination, the ovule primordia divide several times to produce a nucellar filament which consists of five to six cells. The subterminal cell of the nucellar filament enlarges to become the archesporial cell. Through further enlargement and elongation, the archesporial cell becomes the megasporocyte. An unequal dyad results from the first meiotic division. A triad of one active chalazal megaspore and two inactive micropylar megaspores are the end products of meiotic division. Callose is present in the cell wall of the megaspore destined to degenerate. In the mature embryo sac the number of nuclei is reduced to six when the chalazal nuclei fail to divide after the first mitotic division. The chalazal nuclei join the polar nucleus and the male nucleus near the center of the embryo sac subsequent to fertilization.