ULTRASTRUCTURE OF MEIOSIS IN DASYA BAILLOUVIANA (RHODOPHYTA). II. PROMETAPHASE I—TELOPHASE II AND POST-DIVISION NUCLEAR BEHAVIOR1

This is the second of two papers which together are the first comprehensive ultrastructural report of meiosis in a red alga. Many details of the meiotic process in Dasya baillouviana (Gmelin) Montagne are the same as those reported previously for mitotic cells in ceramialian red algae, but several characteristics seem unique to meiotic cells. The nucleus and nucleolus of meiotic cells are larger than those of mitotic cells and large accumulations of smooth ER are often found at the division poles during meiosis 1. The function of the ER accumulations is unknown. Importantly, both interkinesis and a simultaneous division of two separate nuclei during meiosis II was demonstrated. These new observations fail to support earlier speculation on higher red algae for a “uninuclear” meiosis (both nuclear divisions within the same nuclear envelope). However, following meiosis II the four nuclei migrate centripetally and possibly fuse in the center of the tetrasporangium. This post-division nuclear maneuvering is not understood, but our interpretation accounts for the earlier and erroneous impression of “uninuclear” meiosis. Perhaps the most important aspect of meiosis observed in Dasya is its basic adherence to the pattern commonly seen in higher plants and animals. This conservatism of the meiotic process lends further skepticism to the belief that red algae are extremely “primitive” organisms, although they undoubtedly represent a very “ancient” group of eukaryotic plants.     

Meiotic cytokinetic apparatus in the formation of the linear spore tetrads of Conocephalum japonicum (Bryophyta)

Most bryophytes produce tetrahedral spore tetrads. However, linear spore tetrads have been reported to occur in Conocephalum japonicum (Thunb.) Grolle. In this study, the distribution of microtubules (MTs) during meiosis in C. japonicum was examined to determine the division pattern resulting in a linear tetrad. Spore mother cells in the pre-meiotic stage were cylindrical with randomly distributed cytoplasmic MTs. In the prophase-metaphase transition, spindle MTs replaced cytoplasmic MTs and a barrel-shaped spindle with two flattened poles developed. Cortical MT arrays were not detectable throughout meiosis. Although a phragmoplast appeared between sister nuclei in telophase-I, it disappeared without expanding to the parental cell wall. Metaphase-II spindles oriented parallel to the long axis of the cell and in tandem to each other resulted in a linear arrangement of telophase nuclei. Radial arrays of MTs developed from the nuclear surfaces and three phragmoplasts appeared among the four nuclei to produce four spores. Two phragmoplasts separating the paired sister nuclei appeared prior to the appearance of a phragmoplast between non-sister nuclei. The MT cycle is basically the same as that reported in meiosis of C. conicum, which produces non-linear tetrads. A morphometric study indicated that the difference in the division pattern between C. conicum and C. japonicum is due to a difference in the shape of spore mother cells. The cylindrical shape of sporocytes of C. japonicum restricts the orientation of spindles and phragmoplasts so that the four resultant spores are arranged linearly. Received: 22 April 1998 / Accepted: 15 May 1998     

Nuclear cytoplasmic domains,microtubules and organelles in microsporocytes of the slipper orchid Cypripedium californicum A. Gray dividing by simultaneous cytokinesis

Microsporocytes of the slipper orchidCypripedium californicum A. Gray divide simultaneously after second meiosis. The organization and apportionment of the cytoplasm throughout meiosis are functions of nuclear-based radial microtubule systems (RMSs) that define domains of cytoplasm - a single sporocyte domain before meiosis, dyad domains within the undivided cytoplasm after first meiosis, and four spore domains after second meiosis. Organelles migrate to the interface of dyad domains in the undivided cytoplasm after first meiotic division, and second meiotic division takes place simultaneously on both sides of the equatorial organelle band. Microtubules emanating from the telophase II nuclei interact to form columnar arrrays that interconnect all four nuclei, non-sister as well as sister. Cell plates are initiated in these columns of microtubules and expand centrifugally along the interface of opposing RMSs, coalescing in the center of the sporocyte and joining with the original sporocyte wall at the periphery to form the tetrad of microspores. Organelles are distributed into the spore domains in conjunction with RMSs. These data, demonstrating that cytokinesis in microsporogenesis can occur in the absence of both components of the typical cytokinetic apparatus (the preprophase band of microtubules which predicts the division site and the phragmoplast which controls cell-plate deposition), suggest that plant nuclei have an inherent ability to establish a domain of cytoplasm via radial microtubule systems and to regulate wall deposition independently of the more complex cytokinetic apparatus of vegetative cells.     

洋葱小孢子母细胞减数分裂过程中微管分布变化

应用间接免疫荧光标记技术和激光共聚焦扫描显微镜成像技术观察洋葱小孢子母细胞减数分裂过程中微管分布变化。减数分裂之前,小孢子母细胞中的微管较短,呈辐射状,由细胞核表面向四周扩散。减数分裂开始后,细胞质中的一部分微管蛋白聚集成纺锤体微管,控制染色体的分布。进入减数分裂I后期,纺锤体微管变为牵引染色体移向两极的着丝粒微管和连接纺锤体两极的极丝微管。之后,所有微管集中在两个核之间,构成成膜体。然后,微管解聚成微管蛋白弥散在细胞质中。减数分裂I完成后,二分体2个子细胞中的微管蛋白又聚集成2个纺锤体微管,开始减数分裂II过程。经过减数分裂II中期,2个二分体细胞中的微管再次集中在2个细胞核之间形成成膜体,隔离2个细胞核。此后,微管蛋白解聚,弥散分布在小孢子细胞质中。     

Chromosome cycles of the basidiomycete Cyathus stercoreus (Schw.) De Toni

Summary Chromosome cycles of the basidiomycete Cyathus stercoreus (meiosis and mitosis) are described. The fusion of two nuclei of compatible mating type takes place in the developing basidium at the end of telophase of the presynaptic mitosis. Synapsis follows immediately after nuclear fusion. During synapsis the chromosomes elongate, facilitating pairing. Meiosis and mitosis are essentially similar to those processes in higher organisms. Details of divisional stages are described and illustrated with photomicrographs. The presence of centrioles and spindles is demonstrated. The presence of quadrivalents as well as secondary associations of like chromosomes suggests that Cyathus stercoreus may be a tetraploid species.     

Some aspects of microsporogenesis of Welwitschia mirabilis Hook

Abstract

Microsporogenesis in Welwitschia mirabilis was studied by light and electron microscopy. The meiotic process is rapid, asynchronous and a regular aggregation of organelles was observed. In early prophase I the plastids and the mitochondria are positioned around the nucleus. At telophase I they are disposed in the equatorial plane of the meiocyte between the two nuclei of the dyad. At the end of telophase II they are arranged among the four nuclei of the tetrad. Microsporogenesis ends with simultaneous cytokinesis. Degeneration of meiocytes was often observed inside pollen sacs and appeared to be induced by environmental factors.     

Defects in cytoskeletal microtubule deployment of microsporocytes contribute to fertility loss in genic male-sterile Chinese cabbage

The microtubular cytoskeleton of male-sterile Chinese cabbage was examined to characterize cytoplasmically based defects during microsporogenesis of fertile and sterile microsporocytes. At the onset of meiosis, microtubules (MTs) in fertile microsporocytes were short and anisotropically oriented in the microsporocyte cytoplasm. As the microsporocytes entered metaphase I, the MTs constructed a bisymmetrical spindle characterized by conspicuous kinetochore fibers closely associated with chromosomes in the medial plane. During anaphase I, interzonal MTs become conspicuous between the two sets of chromosomes and the polar regions become more distant as spindle MTs are depleted, essentially disappearing at telophase I. Radially distributed MTs increased and the microsporocyte entered meiosis II, producing two spindles at angles to one another within the wall of the microsporocyte. Indicative of the completion of anaphase II is the formation of a field of aligned MTs between two non-sister nuclei, after which the cytoplasm produced centripetal furrows, meeting in the center of the cell and dividing it into four microspores at the completion of cytokinesis. In sterile microsporocytes, however, an abnormal arrangement of MTs occurred at the conclusion of anaphase II. Although two spindles formed, the angle and the boundary between the spindles were not maintained. At the onset of telophase II, the two spindles migrated to a central region and laterally fused in irregular orientations in which the decondensing chromatin of the non-sister nuclei may form separate or merged nuclei, followed by irregular cytokinesis. The result of meiosis was 41.8 % two binuclear products, and 58.2 % one diploid and one binuclear sterile products.     

A COMPARATIVE LIGHT- AND ELECTRON-MICROSCOPIC STUDY OF MICROSPOROGENESIS IN MALE STERILE (MS,) AND MALE FERTILE SOYBEANS (GLYCINE MAX (L.) MERR.)

A comparative study of microsporogenesis in fertile and in male sterile (ms₁) soybean plants (Glycine max (L.) Merr.) was conducted by using various microscopic techniques. Once the developmental pattern for fertile microsporogenesis was established, it was compared with the developmental pattern in sterile plants to determine the time of microsporogenesis breakdown. Sterility of the ms₁ mutant is caused by failure of cytokinesis after telophase II. The four nuclei resulting from meiosis become enclosed in a single-celled structure, termed a coenocytic microspore. These microspores develop a pollen-like wall and become engorged with lipid and starch reserves. Coenocytic microspores usually degenerate after engorgement. This study of fertile and sterile (ms₁) microsporogenesis has shown that nuclear and cytoplasmic events must occur at precise times for the successful development of 1n pollen grains from 2n sporogenous cells. Any disruption during this process leads to sterility.     

Nuclear division of the vegetative cells, conchosporangial cells and conchospores of Porphyra yezoensis (Bangiales, Rhodophyta)

To confirm the position and timing of meiosis in Porphyra yezoensis Ueda, the nuclear division of vegetative cells, conchosporangial cells and conchospores was observed. An improved staining method using modified carbol fuchsin was introduced to stain the chromosomes of Porphyra. Pit‐connections between conchosporangial cells also stained well with this method. Leptotene, zygotene, pachytene, diplotene, diakinesis, metaphase, anaphase and telophase were observed in the conchosporangial cells. During the germination of conchospores, no characteristics of meiosis I were found. No difference between the nuclear division of vegetative cells and that of conchospores was observed, and 2–3 days were needed for the first cell division both in vegetative cells and conchospores. Therefore, the cell division that occurs during conchospore germination is not meiosis I. Our results indicate that the prophase of meiosis I begins during the formation of conchosporangial branches, and metaphase I, anaphase I and telophase I take place during the maturation of conchosporangial branches. Then the three‐bivalent nucleate sporangia complete cell division to form two individual conchospores, each with one three‐univalent nucleus. The conchospores released from the sporangia are at meiotic interphase. Meiosis II occurs at the first nuclear division during conchospore germination, which is a possible explanation for the observation of mosaic thalli in mutant germlings of P. yezoensis. The mosaic thalli might also arise from gene conversion/post meiotic segregation events, comparable to those in Sordaria fimicola (Roberge ex Desm.) Ces. & De Not. and Neurospora crassa Shear & B.O. Dodge.     

ULTRASTRUCTURE OF CELL DIVISION AND REPRODUCTIVE DIFFERENTIATION OF MALE PLANTS IN THE FLORIDEOPHYCEAE (RHODOPHYTA): CELL DIVISION IN POLYSIPHONIA1

Cell division in the marine red algae Polysiphonia harveyi Bailey and P. denudata (Dillwyn) Kutzing was studied with the electron microscope. Cells comprising the compact spermatangial branches of male plants were used exclusively because of their small size, large numbers and the ease with which the division planes can be predetermined. Some features characterizing mitosis in Polysiphonia confirm earlier electron microscope observations in Membranoptera, the only other florideophycean algae in which mitosis has been studied in detail. Common to both genera are a closed, fenestrated spindle, perinuclear endoplasmic reticulum, a typical metaphase plate arrangement of chromosomes, conspicuous, layered kinetochores, chromosomal and non-chromosomal microtubules, and nucleus associated organelles (NAOs) known as polar rings (PRs) located singly in large ribosome-free zones of exclusion at division poles in late prophase. However, other features, unreported in Membranoptera, were observed consistently in Polysiphonia. These include the presence of PR pairs in interphase-early prophase cells, the attachment of PRs to the nuclear envelope during all mitotic stages, the migration of a single PR to establish the division axis, a prominent, nuclear envelope protrusion (NEP) at both division poles at late prophase, the prometaphase splitting of PRs into proximal and distal portions, and the reformation of post-mitotic nuclei by the separation of an elongated interzonal nuclear midpiece at telophase. During cytokinesis, cleavage furrows impinge upon a central vacuolar region located between the two nuclei and eventually pit connections are formed in a manner basically similar to that reported for other red algae. Diagrammatic sequences of proposed PR behavior during mitosis are presented which can account for events known to occur during cell division in Polysiphonia. Mitosis is compared with that reported in several other lower plants and it is suggested that features of cell division are useful criteria to aid in the assessment of phylogenetic relationships of red algae.     

Cytological studies on meiosis and male gametophyte development in autotetraploid cucumber

With improved staining and chromosome preparation techniques, meiosis of pollen mother cells (PMCs) and male gametophyte development in autotetraploid cucumber (Cucumis sativus L.) was studied to understand the correlation between chromosomes behaviour and fertility. Various chromosome configurations, e.g. multivalent, quadrivalents, trivalents, bivalents and univalents were observed in most PMCs at metaphase I. Lagging chromosomes were frequently observed at anaphase in both meiotic divisions. In addition, chromosomes segregations were not synchronous and equal in some PMCs during anaphase II and telophase II. Dyads, triads, tetrads with micronuclei and polyads were observed at tetrad stage, and the frequencies of normal tetrad with four microcytes were only 55.4 %. The frequency of abnormal behaviour in each stage of meiosis was counted, and the average value was 37.2 %. The normal meiotic process could be accomplished to form the microspore tetrads via simultaneous cytokinesis. Most microspores could develop into fertile gametophytes with 2 cells and 3 germ pores through the following stages: single-nucleus early stage, single-nucleus late stage and 2-celled stage. The frequency of abnormalities was low during the process of male gametophyte development. The germination rate of pollen grains was 46.9 %. These results suggested that abnormal meiosis in PMCs was the reason for low pollen fertility in the autotetraploid cucumber.     

Microtubule organization during successive microsporogenesis in Allium cepa and simultaneous cytokinesis in Nicotiana tabacum

Microtubule cytoskeleton organization during microspore mother cell (MMC) meiosis in Allium cepa L. and microsporogenesis in Nicotiana tabacum L. was examined. The MMC microtubules (MTs) were short and well dispersed in the cytoplasm of both taxa. As the MMCs of both species entered metaphase of meiosis I, the MTs constructed a spindle that facilitated the chromosomes to orient in the meridian plane. At anaphase of meiosis I, the spindle MTs differentiated into two types: one MT type became short, pulled the chromosomes toward the two poles, and was designated as centromere MTs; the second type of MT connected the two poles, and was designated as pole MTs. In A. cepa, where successive cytokinesis was observed, pole MTs assumed a tubbish shape. Some new short MTs aggregated in the meridian plane and constricted to form a phragmoplast, which developed into a cell plate, divided the cytoplasm into two parts and produced a dyad. However, in tobacco, a phragmoplast was not generated in anaphase of meiosis I and II and cytokinesis did not occur. The spindle MTs depolymerized and reorganized the radial arrangement of MTs from the nucleate surface to the periplasm during anaphase. Following telophase of meiosis II, the cytoplasm produced centripetal furrows, which met in the center of the cell and divided it into four parts, serving as a form of cytokinesis. In this process, MTs appeared to bear no relationship to cytokinesis.     

ULTRASTRUCTURE OF MITOSIS AND CYTOKINESIS IN KLEBSORMIDIUM MUCOSUM NOV. COMB., FORMERLY ULOTHRIX VERRUCOSA (CHLOROPHYTA)1

A transmission electron microscopy study of dividing cells of Ulothrix verrucosa Lokhorst has provided clear evidence that this species differs in many respects from other Ulothrix Kützing species. These differences include the presence of a microtubular sheath around the prophase nucleus, the complete disintegration of the nuclear envelope coinciding with the proliferation of extranuclear microtubules into the prometaphase nucleus and the intrusion of vacuoles into the interzonal spindle region in between the widely separated telophase nuclei. This necessitates the transfer of Ulothrix verrucosa to the charophycean genus Klebsormidium Silva, Mattox and Blackwell. The new combination Klebsormidium mucosum is proposed. On account of its mitotic pattern, this species can be placed in the (charophycean) evolutionary line towards the higher plants. However, because of its cytokinesis (annular centripetal ingrowth of the plasmalemma) this species probably should be considered as a blind offshoot of this line. It is emphasized that furrowing green algae with a persistent interzonal spindle at telophase (including the presently studied alga) often show an ill-defined cytokinetic microtubular system.     

Cytomorphological study of Scutellaria platystegia (Lamiaceae) in Iran

Chromosome number, meiotic behaviour and morphological characters related to habit were studied in 10 populations of Scutellaria platystegia Juz. from S. sect. Lupulinaria native to Iran. All populations are diploid and has the chromosome number 2n = 2x = 22, which is consistent with the proposed base number of x = 11. This taxon displayed regular bivalent pairing and chromosome segregation at meiosis. However, some meiotic abnormalities observed included various degrees of fragmented chromosomes, laggards and bridges in anaphase I to telophase II, precocious division of centromeres in metaphase I or II, asynchronous nucleus and cytomixis. We evaluated and determined the population limits within S. platystegia, employing multivariant statistics. We found a striking association between meiotic behaviour and gross morphology. (© 2013 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

A differential phenotypic expression of a divergent spindle mutation in interspecific Brachiaria hybrids

Several mutations are known to alter the normal progression of meiosis and can be correlated with defects in microtubule distribution. The dv mutation affects the spindle organization and chromosomes do not converge into focused poles. Two Brachiaria hybrids presented the phenotypic expressions of dv mutation but exhibited many more details in the second division. Bivalents were distantly positioned and spread over a large metaphase plate and failed to converge into focused poles. Depending on the distance of chromosomes at the poles, telophase I nuclei were elongated or the chromosomes were grouped into various micronuclei of different sizes in each cell. The first cytokinesis occurred. However, when there were micronuclei, a second cytokinesis immediately took place dividing the prophase II meiocytes into three or four cells. In each meiocyte, meiosis progressed to the second division. Slightly elongated nuclei or micronuclei were recorded in telophase II. After a third cytokinesis, hexads or octads were formed. Pollen grains of different sizes were generated. One of these hybrids presented a higher frequency of abnormal cells than when previously analyzed. The fate of these hybrids as genitors or as candidates for cultivars in the Brachiaria breeding program is discussed.     

The B-chromosome system of Hypochoeris maculata

The meiotic process in PMCs of Hypochoeris maculata is progressively disrupted in the presence of two or more B-chromosomes. Bivalent formation and chiasma conditions are unaffected by up to 3Bs although some univalence occurs with higher numbers. Spindle behaviour, however, is inefficient at both first and second division in the presence of two or more Bs. At metaphase I, regular equatorial alignment breaks down and A-bivalents sometimes show amphitelic or monosyntelic orientation. Anaphase I is characterised by irregular segregation, equatorial laggards and centric division products. The proportion of normal anaphase segregations declines by 20% for every B more than one. A-chromosome laggards, but not Bs, can induce nuclear restitution at telophase I. Following centric division at anaphase II poleward movement can fail leading to further nuclear restitution. Telophase II nuclei thus can be approximately haploid, diploid or tetraploid with aneuploid variation around the haploid and diploid levels. The frequency of numerical mutants in the offspring indicates that EMC meiosis is much less susceptible to the presence of Bs than PMC meiosis: only 4- and 5B^t plants have an enhanced frequency of numerically-aberrant offspring. The deleterious effects of Bs on meiotic efficiency will contribute to setting an upper limit on B-numbers in natural populations of this species.     

Chromosome numbers, meiotic behavior, and pollen viability of species of Vriesea and Aechmea genera (Bromeliaceae) native to Rio Grande do Sul, Brazil

Chromosome number, meiotic behavior, and pollen viability were analyzed in 15 species of two genera, Vriesea and Aechmea, native to Rio Grande do Sul, Brazil. This study is the first cytogenetic analysis of these taxa. The chromosome numbers are all n = 25, consistent with the proposed base number of x = 25 for Bromeliaceae. All examined taxa displayed regular bivalent pairing and chromosome segregation at meiosis. Observed meiotic abnormalities include univalents in metaphase I; missing or extra chromosomes and precocious division of centromeres in metaphase II; laggards in telophase I and anaphase II/telophase II. The high pollen viability (>88%) reflects a regular meiosis.     

Flavanols in somatic cell division and male meiosis of tea (Camellia sinensis) anthers

Young anthers excised from closed tea flower buds ( Camellia sinensis L.) were stained as fresh tissues with p-dimethylaminocinnamaldehyde reagent to localize flavanols associated with nuclei and chromosomes, apart from those flavanols stored in vacuoles. This staining reagent yields a blue colour for flavanols. In the nonsporogenic somatic cells of developing anthers, flavanols were found to be attached to chromosomes at all mitotic stages. Male meiosis started at a bud size of about 3.5 mm in diameter in pollen mother cells which displayed generally more or less pronounced blue nuclei and cytoplasm. The meiotic divisions from prophase I to telophase II were characterized by blue stained nuclei and chromosomes, but within the cytoplasm there was, if any, a random and very poor reaction for flavanols. Metaphase and telophase of meiotic divisions showed maximally condensed chromosomes staining dark blue. Early in telophase II, the cytoplasm was again stained blue; this faded at late tetrad stage. Flavanols of young mitotic and older non-mitotic anthers were determined using high pressure liquid chromatography--chemical reaction detection (HPLC-CRD). Catechin, epicatechin, B2, and epigallocatechin were minor compounds, whereas epicatechin gallate and epigallocatechin gallate were found in higher amounts. The major flavanol compound of the anthers, epicatechin gallate, exhibited a significant affinity to histone sulphate, as shown by UV-VIS spectroscopic titration.