Sequential protein-dependent steps in the cell cycle initiation and completion of division in vitamin B12 replenishedEuglena gracilis

Summary InEuglena gracilis Z, vitamin B₁₂ deficiency arrests cell divisions in S/G 2 phase. After the addition of vitamin B₁₂ to blocked cells, nuclear and cellular divisions begin to be induced between the 3rd and the 4th and between the 4th and the 5th hour respectively; the cell population is doubled after the 11th hour.Addition of cycloheximide either with vitamin B₁₂ or 2 to 6 hours later inhibits the resumption of divisions and blocks cell development in different stages between G 2, karyokinesis and cytokinesis. These results suggest that as a prerequisite protein-dependent steps are required at precise times during the reversibility of blocked cell divisions: at least sequential syntheses of protein concern a) formation of the mitotic spindle and replication of the pellicle; b) completion of the nuclear division; c) progression of the cleavage furrow.     

The Fertilization and Early Development of Embryo and Endosperm in Stevia rebaudiana Bertani

The mature embryo sac is surrounded by endothelium tapetum. It is composed or an egg apparatus, one central cell with secondary nucleus, and 1–6 antipodal cells. About the 6th hour after pollination, female and male nuclei fuse with each other. The syngamy occurred almost simultaneously with the fusion of an other sperm nucleus and the secondary nucleus, but the velocity of the latter is faster than that of the syngamy. The fertilization of Stevia rebaudiana Bertani belongs to the premitotic type. About the 8th hour after pollination, primary endosperm nucleus is in mitosis, its dividing orientation may parallel or at right angle to the long axis of the embryo sac, and gives rise to two initial endosperm cells. The first five divisions of the endosperm cells are of synchronism. At the stage of heart-shaped embryo, the endosperm cells show the signs of digestion and absorbed. The endosperm development is of the cellular type. About the 10th hour after pollination, zygote divides for the first time. The division of the zygote is always transverse. The embryo development conforms to the Asterad type.     

黄花油点草胚胎发育研究

利用石蜡切片技术对百合科植物黄花油点草[Tricyrtis maculata(D.Don)Machride]双受精、胚及胚乳发育进行了研究,以明确其胚胎发育的特征,为百合科植物的系统研究提供生殖生物学资料。结果表明:(1)黄花油点草为珠孔受精;进入胚囊的2枚精子分别与卵细胞和中央细胞进行正常的双受精,其受精作用属有丝分裂前型。(2)受精后的初生胚乳核立即分裂,其发育方式为核型胚乳;早期的游离胚乳核沿胚囊的边缘分布,胚囊中央部位主要为胚乳细胞质,随着游离胚乳核数量的增加,胚乳核慢慢充满整个胚囊;当发育至球形胚早期阶段,在各胚乳核周围产生胚乳细胞壁,形成完整的胚乳细胞。(3)合子有较长的休眠时间,胚的发育方式为茄型;合子第一次有丝分裂为横裂,分裂后形成基细胞和顶细胞;基细胞经过3次横裂,形成一列胚柄细胞;顶细胞经过分裂形成胚体,依次形成球形胚、棒状胚和盾形胚。(4)种子成熟时胚无器官分化;成熟种子由种皮、胚和胚乳三部分组成。     

Extra divisions and nuclei fusions in microspores from Brassica allohexaploid (AABBCC) × Orychophragmus violaceus hybrids

Abnormal meiosis and microspore development and related defective mutants have often been reported in plants and wide hybrids. Here extra divisions and nuclei fusions were observed to occur in microspore nuclei of partial hybrids between synthetic Brassica hexaploid (2n=54, AABBCC) and another crucifer Orychophragmus violaceus (2n=24). Abnormal spindle were formed and chromosomes were separated into several nuclei of variable sizes after bi-, or multi-polar divisions in the four cells of tetrads. As a consequence, more than eight mini-microspores of different sizes were produced by one tetrad. Genomic in situ hybridization results indicated that no chromosome replication occurred during such divisions. In some tetrads, the four nuclei were fused to form one large cell with increased chromosome number. The extra divisions or fusions appeared only in some flower buds of one plant, some anthers in the same buds, or even in individual cells of tetrads. The possible mechanisms behind these cytological phenomena are discussed.     

WHAT DO WE KNOW ABOUT CHAROPHYTE (STREPTOPHYTA) LIFE CYCLES?1

The charophyte algae are the closest living relatives of land plants. Their life cycles are usually characterized as haploid with zygotic meiosis. This conclusion, however, is based on a small number of observations and on theoretical assumptions about what kinds of life cycle are possible. Little is known about the life cycles of most charophytes, but unusual phenomena have been reported in comparatively well‐studied taxa: Spirogyra and Sirogonium are reported to produce diploid gametes with synapsis of homologous chromosomes before fusion of gametic nuclei; Closterium ehrenbergii is reported to undergo chromosome reduction both before and after syngamy; and zygotes of Coleochaete scutata are reported to replicate their DNA to high levels before a series of reduction divisions. All of these phenomena require confirmation, as does the conventional account.     

A NOVEL PATTERN OF APICAL CELL POLYPLOIDY,SEQUENTIAL POLYPLOIDY REDUCTION AND INTERCELLULAR NUCLEAR TRANSFER IN THE RED ALGA POLYSIPHONIA

Nearly a century ago, Rosenvinge published a now-classic paper reporting nuclear transfer between cells of Polysiphonia during secondary pit connection (SPC) formation. While reinvestigating this phenomenon, we discovered that the uninucleate apical cell, which is the progenitor of all cells in the plant, has many times (ca. 64–128 ×) the level of nuclear DNA characteristic of nuclei of gametes or mature pericentral cells. Via a regular sequence of cell divisions, the polyploid apical cell gives rise to tiers of cells, each composed of a number of pericentral cells which surround a single central cell. A large proportion of the nuclear divisions are not accompanied by DNA replication. Thus, as the number of nuclei within elongating pericentral cells increases, the DNA level of nuclei in these cells “cascades” down to the DNA level expected for the particular life history generation (i.e., gametophyte or tetrasporophyte). In mature pericentral cells, the number of nuclei is proportional to the volume of the cell. The pattern of nuclear division, reduction in ploidy level and the timing of intercellular nuclear transfer via SPC formation is regular and characteristic of a species. Nuclei transferred from one cell to an adjacent cell participate in the further nuclear divisions of the recipient cell. The degree of polyploidy in apical cells may determine the number of cells in a “determinant” branch or even the number of cells in “indeterminant” axes. In addition, the highly polyploid state of the germinating spore and its pattern of development may provide for the rapid initial growth so characteristic of this taxon.     

The Fusion of Male and Female Nuclei in Fertilization of Higher Plants

Studies on the fusion of male and female nuclei in fertilization of Helianthus an- nuus L., Triticum aestivan L., Gossypium hisutum L., Hosta caerulea Tratt., and Pinus tabulaeformis Carr. were made in the present work. The results are summarized as follows: 1. The essential process of the fusion of male and female nuclei during syngamy in four species of angiosperms studied may' be generalized as follows: (1) the male nucleus made contact with the female one, (2) followed by the fusion of nuclear membranes between the male and female nuclei. (3) then the despiralization of male spireme happened and male nucleolus made its appearance inside of the fertilized egg nucleus (4) the male chromatin dispersed and make its appearance indistinguishable from that of the female chromatin, (5) the male and female nucleoli fused together to form a larger nucleolus as a sign of completion of the fusion of the two nuclei. In the first mitotic division of the zygote there was only one common mitotic spindle. 2. The essential process of the fusion of egg and sperm nuclei during syngamy in a gymnosperm-Pinus tabulaeformis could also be outlined as follows: (1) the sperm nucleus made contact with the egg nucleue, (2) the fusion of nuclear membranes happened between the male and female nuclei, (3) the male and female ehromatins condensed to form two separate groups of chromatin threads together with the very apparent apperance of the male and female nucleoli at this stage, (4) the male and female chromosomes grouped respectively in their own spindles while both nucleoli disappeared, (5) then the two spindles fused together and all the chromosomes arranged to form a common equatorial plate, (6) finally two daugter nuclei resulted from the mitotic division. 3. Based on the facts that there were two different patterns of the fusion of male and female nuclei in fertilization discribed, all of these accounts are in general accord with the condition usually described that there are two types of fertilization, the pre- mitotic and postmitotie syngamy in higher plants. The type of angiosperm fertilization and the mechanism of promoting the zygote to divide after fertilization are discussed, and the nuclear fusion in sexual reproduction has been compared with that of somatic cell hybridization.     

Glugea gasti sp. n., a Microspridan Pathogen of the Boll Weevil Anthonomus grandis1,2,3

SYNOPSIS. Glugea gasti sp. n., a microsporidan pathogen of Anthonomus grandis Boheman (the boll weevil), is described and a probable life cycle presented. The alimentary canal, and probably the mesenteron 1st, is the initial site of infection, altho the disease later becomes generalized thruout most body tissues. Binucleate sporoplasms initiate the 1st schizogonic phase, characterized by mono- and bi-nucleate schizonts. The 2nd schizogonic phase is characterized by mono-, bi- and quadrinucleate schizonts, by prolific multiplication, by the dense compact nuclei early in this phase, and late in this phase by larger schizonts with less dense vesicular nuclei. This phase terminates in formation of diplokarya. The sporogonic phase is characterized by combination of the 2 nuclei in the diplokaryon followed by nuclear divisions in a sequence closely resembling meiosis. Two sporoblasts are produced from each sporont. Mature spores in wet mounts by phase contrast were 4.3 ± 0.3 μ long by 2.3 ± 0.2 μ wide. The polar filament averaged 76 μ long. Mature spores were present about 24 hours after infection. Some observations are presented on an external filament extending from one pole of the spore to host tissue and other events during the process of spore morphogenesis.     

糙皮侧耳染色体计数和担孢子形成过程中细胞核行为的研究

糙皮侧耳(Pleurotus ostreatus)菌褶经有丝分裂阻断剂预处理、原生质体铺片和Gie-msa 染色并结合苏木精染色后,经过多次反复实验观察,证明糙皮侧耳的染色体条数为 9(n=9);糙皮侧耳从菌褶分化完成到子实体完全成熟的过程中,不断有少量新的双核担子产生,发生核配直到释放担孢子。其减数分裂同步性不高。减数分裂后,4个子核分别进入4个担孢子中,留下中空的担子。     

Sélection,par les chromosomes en écouvillon,de lignées vectrices de mutations chez l'amphibien urodèle Pleurodeles poireti

Division of the guard mother cell (GMC) in Allium cotyledons has been examined in epidermal slices viewed with Nomarski optics and electron microscopy. Special attention has been directed towards elucidating the process by which the dividing cell determines its plane of division. In normal development, the cell plate formed during GMC division ultimately lies along the longitudinal axis of the cotyledon, in contrast to the transverse planes formed in other epidermal divisions. Our observations reveal that the final plane of division is not determined by the orientation of the spindle at metaphase but instead is established during late anaphase-telophase as a result of directed reorientation movements of the spindle-phragmoplast and associated daughter nuclei. The metaphase plate may lie at an oblique angle, even as great as 90°, from the final plane of the plate. Thus, daughter chromosomes separate into opposite corners of the cell. During late anaphase-telophase, movement of the spindle is activated; the daughter nuclei move along the sides of the cell while the interzone rotates. Movement continues until daughter nuclei reach positions opposite each other along the sides of the cell and the midzone or cell plate is positioned in the longitudinal orientation. Movement requires 15–20 minutes for completion, is highly directional, and does not overshoot the correct alignment. Following movement cytokinesis proceeds to completion forming two young guard cells. Possible mechanisms for reorientation are discussed, including one that suggests that interzone microtubules may interact with a cortical site on the plasmalemma adjacent to the end and paradermal walls. Such a site may be related to and governed by the same properties which controlled the prior formation of the preprophase band of microtubules in these cells.     

Fertilization and rejection of spermatozoids by egg cells in artificially pollinated ovules ofEncephalartos (Zamiaceae)

The structure and behaviour of free female, male and proembryonal nuclei ofEncephalartos villosus Lem. were studied during a light-microscopical investigation of serially sectioned archegonia in successfully pollinated ovules. Before spermatozoids were released from the pollen tubes into the archegonial chamber, the ventral canal nucleus had disintegrated in the neck region of the egg cell among minute, amoeboid bodies with PAS-positive granules. In archegonia containing multiple spermatozoids, the egg nucleus was unobtrusive and syngamy followed by proembryo formation regularly resulted. The egg cell usually reacted violently in archegonia penetrated by a single spermatozoid. These reactions were regarded as rejection phenomena and considered as indicators that the egg cell can differentiate between compatible and incompatible male gametes.     

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

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

Time-course analysis of nuclear events during conjugation in the marine ciliate Euplotes vannus and comparison with other ciliates (Protozoa,Ciliophora)

Ciliates represent a morphologically and genetically distinct group of single-celled eukaryotes that segregate germline and somatic functions into two types of nuclei and exhibit complex cytogenetic events during the sexual process of conjugation, which is under the control of the so-called “mating type systems”. Studying conjugation in ciliates may provide insight into our understanding of the origins and evolution of sex and fertilization. In the present work, we studied in detail the sexual process of conjugation using the model species Euplotes vannus, and compared these nuclear events with those occurring in other ciliates. Our results indicate that in E. vannus: 1) conjugation requires about 75 hours to complete: the longest step is the development of the new macronucleus (ca. 64h), followed by the nuclear division of meiosis I (5h); the mitotic divisions usually take only 2h; 2) there are three prezygotic divisions (mitosis and meiosis I and II), and two of the eight resulting nuclei become pronuclei; 3) after the exchange and fusion of the pronuclei, two postzygotic divisions occur; two of the four products differentiate into the new micronucleus and macronucleus, respectively, and the parental macronucleus degenerates completely; 4) comparison of the nuclear events during conjugation in different ciliates reveals that there are generally three prezygotic divisions while the number of postzygotic divisions is highly variable. These results can serve as reference to investigate the mating type system operating in this species and to analyze genes involved in the different steps of the sexual process.     

Developmental regulation of excision timing of Mutator transposons of maize: Comparison of standard lines and an early excision bzl::Mu1 line

Three characteristics of standard Mutator lines reflect developmental regulation: new mutants usually involve single gametes, somatic excision is restricted to terminal cell divisions during tissue development, and germinal excision is rare. By selection for earlier (larger) somatic sectors in the aleurone, a Mutator line was identified that exhibits a dramatic elevation in somatic excision frequency during the first three nuclear divisions of the endosperm and more than a 10-fold increase in germinal reversion from the bzl::Mul reporter gene. The programming of early sectoring is dominant in crosses with Mutator lines containing diverse reporter alleles. Germinal reversion is biased 5- to 10-fold for events through the pollen compared to the ear. The timing of germinal excision in the tassel is late because somatic excision sectors in the anthers are small; however, 98% of the germinal revertants are concordant. These observations indicate that in the early sectoring line Mu excision usually occurs before the mitotic divisions that separate gametic nuclei and may be restricted to the early stages of microsporogenesis. © 1992 Wiley-Liss, Inc.     

Mutation of a putative sperm membrane protein in Caenorhabditis elegans prevents sperm differentiation but not its associated meiotic divisions

Spermatogenesis in the nematode Caenorhabditis elegans uses unusual organelles, called the fibrous body-membranous organelle (FB-MO) complexes, to prepackage and deliver macromolecules to spermatids during cytokinesis that accompanies the second meiotic division. Mutations in the spe-4 (spermatogenesis-defective) gene disrupt these organelles and prevent cytokinesis during spermatogenesis, but do not prevent completion of the meiotic nuclear divisions that normally accompany spermatid formation. We report an ultrastructural analysis of spe-4 mutant sperm where the normally close association of the FB's with the MO's and the double layered membrane surrounding the FB's are both defective. The internal membrane structure of the MO's is also disrupted in spe-4 mutant sperm. Although sperm morphogenesis in spe-4 mutants arrests prior to the formation of spermatids, meiosis can apparently be completed so that haploid nuclei reside in an arrested spermatocyte. We have cloned the spe-4 gene in order to understand its role during spermatogenesis and the molecular basis of how mutation of this gene disrupts this process. The spe-4 gene encodes an approximately 1.5-kb mRNA that is expressed during spermatogenesis, and the sequence of this gene suggests that it encodes an integral membrane protein. These data suggest that mutation of an integral membrane protein within FB-MO complexes disrupts morphogenesis and prevents formation of spermatids but does not affect completion of the meiotic nuclear divisions in C. elegans sperm.     

Repetitive Micronuclear Divisions in the Absence of the Macronucleus During Conjugation of Paramecium caudatum

ABSTRACT. The germinal micronucleus divides six times during conjugation of Paramecium caudatum : this includes two meiotic divisions and one mitosis of haploid nuclei during mating, and three mitoses of a fertilization nucleus (synkaryon). Microsurgical removal of the macronucleus showed that micronuclei were able to divide repeatedly in the absence of the macronucleus, after metaphase of meiosis I of the micronucleus and also after synkaryon formation. When the macronucleus was removed after the first division of synkaryon, in an extreme case the synkaryon divided five times and produced 32 nuclei, compared to three divisions and eight nuclei produced in the presence of the macronucleus. Treatment with actinomycin D (100 μ /ml) inhibited the morphological changes of the macronucleus during conjugation and induced a multimicronucleate state in exconjugants. However, in other cells, it induced production of a few giant micronuclei. We conclude that the micronucleus is able to undergo repeated divisions at any stage of conjugation in the absence of the macronucleus once the factor(s) for induction of the micronuclear division has been produced by the macronucleus. The macronucleus may also produce a regulatory factor required to stop micronucler division.     

Asymmetrical rotations of blastomeres in early cleavage of gastropoda

Summary The movements of blastomere surfaces marked with carbon particles during cytokinesis of the Ist–IVth cleavage divisions in the eggs of the gastropodsLymnaea stagnalis, L. palustris, Physa acuta and Ph. fontinalis have been studied by time-lapse cinematographic methods. The vitelline membrane was removed with trypsin. At 2- and 4-cell stages shifts of nuclei have also been studied.Symmetrical as well as asymmetrical surface movements (in respect to the furrow plane) have been revealed. Symmetrical surface movements at the beginning of cytokinesis consist mainly in contraction of the furrow zone and in expansion of the more peripheral regions; between these there is a stationary zone. After the end of cytokinesis the furrow region expands.Considerableasymmetrical surface movements have also been observed in all four divisions. From anaphase until the end of cytokinesis each of the two sister blastomeres rotates with respect to the other in such a way, that if viewed along the spindle axis, the blastomere nearest to the observer rotates dexiotropically in a dextral species and laeotropically in a sinistral species (primary rotations). After the completion of cytokinesis the blastomeres may rotate in a reverse direction. The latter rotations are less pronounced in the IInd and IIIrd divisions and most pronounced in the IVth division. Blastomeres with the vitelline membrane intact retain a slight capacity for primary rotations. In normal conditions nuclei of the first two blastomeres shift mainly laeotropically in dextral species, but dexiotropically in sinistral species, being carried along by the reverse surface rotations.The invariable primary asymmetrical rotations of blastomeres seem to be the basis of enantiomorphism in molluscan cleavage. They are assumed to be determined by an asymmetrical structure of the contractile ring carrying out the cytokinesis.     

COLONY DEVELOPMENT IN EUDORINA ELEGANS (CHLOROPHYTA,VOLVOCALES)1

A detailed ultrastructure study was made of cell division and colony development in Eudorina elegans Ehrenberg. At the onset of cell division and prior to nuclear division the nucleus moved from the cell center to the cell surface. During nuclear division the nuclear membrane remained intact, except for openings occurring at the nuclear poles. The spindle microtubules appeared to arise from a MTOC-like (microtubule organizing centers) structure, while centrioles were absent from the nuclear poles. Following telophase, daughter nuclei formed which were separated by several distinct bands of endoplasmic reticulum. Cytokinesis occurred with formation of a cleavage furrow, associated with a typical phycoplast band of microtubules. However, cytokinesis was incomplete, resulting in formation of cytoplasmic bridges between the plakeal cells. Upon completion of up to five successive cell divisions, the plakea underwent inversion, which appeared to involve the production of colonial envelope material and rearrangement of cytoplasmic bridges. A new hypothesis concerning inversion is postulated based on these observations.     

Scanning electron microscopy of Drosophila embryogenesis: 1. The structure of the egg envelopes and the formation of the cellular blastoderm

As part of a series of detailed observations on embryogenesis in Drosophila, the protective coverings of the egg and surface changes in the embryo prior to gastrulation have been studied with the SEM. Four specializations of the chorion are described: the plastron, micropylar cone, operculum, and the posterior thickening. After removal of the protective coverings the surface changes during development can be observed. During the first eight synchronous nuclear divisions a dense array of thin microprojections covers the whole embryo. After the ninth division between 373 and 408 nuclei reach the surface and become located in cytoplasmic projections. From counts of the number of surface bulges during the syncytial blastema stages, it was established that 13 synchronous divisions take place producing between 5600 and 6500 surface nuclei. During formation of the cellular blastoderm, the location of the prospective cells becomes obscured by a dense pattern of microprojections from each cell. However, with the completion of the blastoderm, the surfaces of the cells become smooth and the cell outlines distinct. The usefulness of the SEM in developmental studies is discussed.