Observations On Nuclear Division in vegetative hyphae of aquatic fungi

Summary Achlya aquatica, A. prolifera andA. racemosa are additional examples of fungi in whose vegetative mycelium, the nuclei do not divide in a manner directly comparable to ordinary mitosis. During division the entire nucleus, which consists of variously shaped chromatin and the nucleolus, becomes angular and elongates. The chromatin separates into two portions, which are situated at opposite ends of the elongating nucleus. As division proceeds the nuclei separate. Each sister nucleus sonsists of chromatin and a portion of the divided nucleolus. Spindless, chromosomal filaments or metaphase plates could not be observed during division.     

玉米双受精过程的细胞学观察

1.玉米双受精属于有丝分裂前配子融合的类型。2.授粉后21至24小时,大部分雌、雄性核发生融合。雌、雄性核融合时,雄性核仁的出现存在两种情况,其一是精核染色质逐渐分散的同时出现雄性核仁,其二是精核染色质逐渐分散后,约经2至4小时才出现雄性核仁。3.合子内的雌、雄性核仁若发生融合,一般在合子分裂前进行。合子以一个大核仁的形式进入分裂期;雌、雄性核仁不融合的合子同样可以进入分裂期。授粉后30至33小时,合子进行第一次分裂。合子静止期大约为9小时左右。4.初生胚乳核内的雌、雄性核仁不发生融合。授粉后24至26小时,初生胚乳核进行第一次分裂。初生胚乳核的静止期为2—4小时。5.人工授粉条件下,玉米果穗受精过程的进行有一定的顺序;即自果穗上部逐渐向下部完成受精作用。     

CRUCIFORM NUCLEAR DIVISION IN WORONINA PYTHII (PLASMODIOPHOROMYCETES)

Somatic nuclear divisions in sporangiogenous plasmodia of Woronina pythii Goldie-Smith were studied with transmission electron microscopy. During metaphase, each nucleus formed a cruciform configuration as chromatin became aligned at the equatorial plate perpendicular to the persistent nucleolus. Except for polar fenestrations, the original nuclear envelope remained intact throughout the mitotic division. Intranuclear membranous vesicles appeared to bleb off the inner membrane of the original nuclear envelope, adhered to the surfaces of the separating chromatin, and eventually formed new daughter nuclear envelope within the original nuclear envelope. During the first 24 hr of vegetative plasmodial growth, each telophase nucleus exhibited an obvious constriction of the original nuclear envelope in the interzonal region. Similar constrictions were not evident in telophase nuclei found in 24–36-hr-old plasmodia. This variation in the ultrastructural morphology of cruciform division appears to be related to the age and size of each sporangiogenous plasmodium, and is the first to be documented within this group of fungal pathogens.     

MITOSIS AND CLAMP FORMATION IN THE FUNGUS PORIA MONTICOLA

Nuclear division in P. monticola is in general similar to mitosis in higher organisms. Synchronous division of the nuclei in the dikaryon progresses with clamp development. Mitosis begins with the movement of the centriolar plaques into and under the forming clamp. The pull of the centriolar plaque on the attached nucleolus forms a long strand of nucleolar material. Chromosomes now appear as dense granules at the end of the nucleus proximal to the clamp. At this time the nucleolus moves adjacent to the centriolar plaque and contracted chromosomes. The nuclear membrane at least partially disintegrates, and the nucleolus is released into the cytoplasm where it may persist through telophase. A faintly staining spindle is often observed, and it produces a “double bridge” effect in separating chromatin. Somatic chromosomes are attached together forming strings that appear double and at least partially separated before metaphase.     

Microtubule formation on the nuclear surface during meiosis inAcetabularia acetabulum

Summary Microtubules (MT) are a feature of all eukaryotic cells. However, they have not been observed in the cytoplasm of the vegetative phase ofAcetabularia acetabulum. Previous investigators have reported that, in the propagative phase, MTs function as anchors in the transport of secondary nuclei to the cap. They also form elaborate arrays around nuclei during cyst formation. The life history ofA. acetabulum is marked by changes in chromatin, the nucleolus, and the perinuclear cytoplasm. In this study light microscopical features of the nucleolus and changes in chromatin, labelled with anti-histon antibodies, were used to define the developmental stages. Anti-tubulin antibodies have been used to trace the origin and development of MTs, MTs are formed on the surface of the primary nucleus. They are organized first into short thick sticks and then later elongate into thinner strands which enclose the nucleus in a dense network. Following these events on the surface of the nucleus, the spindle develops inside the nuclear membrane which remains intact throughout the mitotic division.     

The developmental fate of angiosperm pollen is associated with a preferential decrease in the level of histone H1 in the vegetative nucleus

In angiosperm pollen, the vegetative cell is assumed to function as a gametophytic cell in pollen germination and growth of the pollen tube. The chromatin in the nucleus of the vegetative cell gradually disperses after microspore mitosis, whereas the chromatin in the nucleus of the other generative cell remains highly condensed during the formation of two sperm nuclei. In order to explain the difference in chromatin condensation between the vegetative and generative nuclei, we analyzed the histone composition of each nucleus in Lilium longiflorum Thunb. and Tulipa gesneriana immunocytochemically, using specific antisera raised against histones H1 and H2B of Lilium. We found that the level of histone H1 decreased gradually only in the vegetative nucleus during the development of pollen within anthers and that the vegetative nucleus in mature pollen after anther dehiscence contained little histone H1. By contrast, the vegetative nucleus contained the same amount or more of histone H2B than the generative nucleus. The preferential decrease in the level of histone H1 occurred in anomalous pollen with one nucleus (uninucleate pollen) or with two similar nuclei (equally divided pollen), which had been induced by treatment with colchicine. The nuclei in the anomalous pollen resembled vegetative nuclei in terms of structure and staining properties. The anomalous pollen was able to germinate and extend a pollen tube. From these results, it is suggested that the preferential decrease in level of histone H1 in pollen nuclei is essential for development of the male gametophytic cell through large-scale expression of genes that include pollen-specific genes, which results in pollen germination and growth of the pollen tube. Received: 9 May 1998 / Accepted: 4 June 1998     

Cytologic Observations on the Double Fertilization in Maize

1.The double fertilization is the type of the premitotic syngamy. 2. In 21 to 24 hours after pollination, most of the female nuclei fuse with the male nuclei. When the female nucleus fuses with the male nucleus, there are two situations in the appearance of the male nucleolus: one is that while the chromatin of the sperm nucleus relaxes gradually, a male nucleolus appears; the other is that after the chromatin of the sperm nucleus relaxes gradually, the male nucleus just appears in about 2 to 4 hours. 3. Generally, the fusion of the female nucleolus with the male nucleolus takes place before the division of the nygote. The nygote enters the stage of division when it has a jarge nucieojus; the zygote, in which the female nucleoius does not fuse with the male nucleolus, also can enter the stage of division. In 30 to 33 hours after pollination, the first division of the zygote occurs. The resting period of the zygote is about 9 hours 4. In the primary endosperm nucleus, the female nucleolus does not fuse with the male nucleolus. 24 to 26 hours after pollination, the primary endosperm nucleus begins the first division. The resting period of the primary endosperm nucleus is 2 to 4 hours. 5. Under the condition of artificial pollination, the fertilization of the fruit ears of maize proceeds sequencely, i.e. from the upper of the fruit ears to the lower the fertilization is fulfilled gradually.     

VEGETATIVE NUCLEAR DIVISION IN NEUROSPORA

A re-examination of the mode of vegetative nuclear division in Neurospora crassa was facilitated by the availability of the mutant “clock” which produces definite growth bands. Since the growth rhythm is correlated with nuclear divisions, stained mycelial mats of this mutant prepared at intervals from the beginning of a growth period provided a sequence of stages of division. In a 28-hour period the following broad features of nuclear behavior were observed: In the early part of the period during rapid mycelial growth, dividing elongated nuclei predominated. At the end of the period the mycelium contained mostly rounded resting nuclei. In the middle of a growth period nuclear forms of various degrees of annularity occurred along with elongated and rounded nuclei. Elongated and rounded nuclei completed division cycles without change in form, although the corresponding stages of the two types were similar. Elongated nuclei assumed a spiral form at the beginning of division. As division proceeded, relaxation of the nuclear gyres was accompanied by a visible duplication of the chromatin thread and the appearance of chromomere-like bodies on the daughter threads. One of the chromomere-like bodies became displaced and was interpreted to be a chromosome or a segment of a chromosome that acts as a mitotic center. All the chromosomes were found to be interconnected and to act as a unit throughout the division cycle. Only after the separation of the daughter chromatin threads could seven chromosomes be counted. Electron microscopic studies complemented the observations with the light microscope. On the basis of the evidence it was concluded that the vegetative nuclear division in Neurospora differs from the classical mitotic pattern in the following respects: (1) absence of visible centrioles, (2) the presence of interconnected chromosomes, (3) the comparatively late appearance of countable chromosomes, and (4) the frequent presence of interzonal connections between separating chromatin threads.     

Ultrastructural localization of nucleic acid sequences in Saccharomyces cerevisiae nucleoli

The putative nucleolus in Saccharomyces cerevisiae is visible in electron micrographs as a darkly stained, crescent-shaped structure associated with the nuclear envelope. The haploid yeast genome contains 100 200 tandem copies of a 9.1 kb ribosomal DNA (rDNA) repeat predicted to reside in this structure. We combined in situ hybridization of non-isotopically labeled probes to isolated S. cerevisiae nuclei with immunogold detection to localize rDNA and rRNA precursor sequences in nuclei at the electron microscope (EM) level. Gold particles are restricted to defined regions of nuclei which appear more electron dense than the bulk of the nucleus and which generally exhibit the crescent shape typical of the structure thought to be the nucleolus. In addition, snR17, the yeast homolog of mammalian U3, a nucleolar-restricted small nuclear RNA (snRNA), was localized to the same electron dense region of the nucleus. These data, in conjunction with published immunofluorescent localizations of nucleolarassociated antigens, provide definitive proof that the dense crescent is the nucleolus. Finally, the technique described is applicable to probing nuclear organization in a genetically manipulable system.Abbreviations snRNA small nuclear RNA - AAF N-acetoxy-2-acetyl-aminofluorence by M.L. Pardue     

Cytological studies on the nuclear differentiation in microspore division of some angiosperms

In all of the 32 species studied the chromatin in one of the daughter nuclei produced by microspore division was found to diffuse earlier than the chromatin of the other. The former developed into a vegetative nucleus and the latter into a generative nucleus. The stage at which this difference between daughter nuclei was first found appeared to vary widely among species. The earliest was found to be at mid-anaphase observed inHemerocallis thunbergii andMagnolia denudata, and the latest at early interphase observed inLilium japonicum, Pogonia japonica andEpipactis thunbergii. InNarcissus jonquilla and 4 other species the nuclear differentiation started at late anaphase, inHaplopappus gracilis and 13 other species at early telophase, and inTradescantia paludosa and 7 other species at mid-telophase.     

An electron microscope study of nuclear and cell division in a dinoflagellate

Summary Light microscopical observations on the cell division of the small dinoflagellate Woloszynskia micra are correlated for the first time with an electron microscopical study. In prophase, whilst the nucleus enlarges and becomes pearshaped, the chromosomes divide to give pairs of chromatids. This process starts at one end and works to the other giving Y- and V-shaped chromosomes as it occurs. Cytoplasmic invaginations pass through the nucleus and by the end of prophase these are seen to contain a number of microtubules of about 180 Å diameter. There is no connection between the microtubules in the nuclear in vagination and either the flagellar bases or the chromosomes. At anaphase the nucleus expands laterally and the sister chromatids move towards opposite ends. The cell hypocone is now partially divided and the two longitudinal flagella well separate. The nucleus completes its division into two daughter nuclei and for a time portions of the cytoplasmic invaginations remain visible. Cell cleavage is completed by the division of the epicone. The nuclear membrane remains intact throughout division and the nucleolus does not break down.The mitotic division in this organism, which is unusual in comparison with the mitosis of higher organisms, is discussed in the light of other types of mitosis which have been reported and of earlier light microscopical observations on dinoflagellates.     

Mitosis in the Hemoflagellate Trypanosoma cyclops*

SYNOPSIS. The ultrastructure of interphase and mitotic nuclei of the epimastigote form of Trypanosoma cyclops Weinman is described. In the interphase nucleus the nucleolus is located centrally while at the periphery of the nucleus condensed chromatin is in contact with the nuclear envelope. The nucleolus fragments at the onset of mitosis, but granular material of presumptive nucleolar origin is often recognizable in the mitotic nucleus. Peripheral chromatin is in contact with the nuclear envelope throughout mitosis, and it seems reasonable to assume that the nuclear envelope is involved in its segregation to the daughter nuclei. Spindle microtubules extend between the poles of the dividing nucleus and terminate close to the nuclear envelope. The basal body and kinetoplast divide before the onset of mitosis and do not appear to have any morphologic involvement in that process. Spindle pole bodies, kinetochores, and chromosomal microtubules have not been observed.     

CYTOLOGY OF HELMINTHOSPORIUM TURCICUM AND ITS ASCIGEROUS STAGE,TRICHOMETASPHAERIA TURCICA

Knox- Davies , P. S., and J. G. Dickson . (U. Wisconsin, Madison.) Cytology of Helmintho sporium turcicum and its ascigerous stage, Trichometasphaeria turcica . Amer. Jour. Bot. 47(5) : 328—339. Illus. 1960.–The cells of the vegetative hyphae were generally multinucleate. Interphase nuclei resembled those of higher organisms, with a matrix of thread-like chromatin material surrounding a spherical nucleolus. “Beaked” nuclei frequently associated with anastomosing hyphae were interpreted as migrating nuclei. Nuclear division in the vegetative hyphae was rapid. Various division stages were distinguished but it was difficult to make accurate chromosome counts. The nucleoli were discarded at prophase or prometaphase and were reorganized in daughter nuclei at telophase. An outstanding feature of nuclear division was that all the nuclei in a cell divided simultaneously. Conidiophores and conidia were occasionally joined by wide cytoplasmic connections. They were multinucleate throughout their development. Mechanisms therefore exist for the perpetuation of heterokaryons through the conidium. Ascus development was studied in a hybrid between a dark and an albino isolate. Crozier formation was typical and nuclear fusion occurred in the young ascus. Four nuclear divisions were completed in the ascus before there was evidence of ascospore delimitation. Further nuclear division took place in the ascospores whose cells were multinucleate. The occurrence of less than 8 ascospores in an ascus appeared to follow degeneration of nuclei rather than the incorporation of a number of division-Ill nuclei in a single ascopore. Chromosome counts and irregularities in the appearance and behavior of nuclei and chromosomes in the asci indicate that aneuploidy occurs in Trichometasphaeria turcica. It is suggested that aneuploidy is a common phenomenon in the conidial stage of the fungus H. turcicum, and possibly also in other imperfect fungi.     

STRUCTURE AND FUNCTION OF THE ALGAL PYRENOID. I. ULTRASTRUCTURE AND CYTOCHEMISTRY DURING ZOOSPOROGENESIS OF TETRACYSTIS EXCENTRICA1

The fine structure of the pyrenoid in the mature vegetative cell of Tetracystis excentrica Brown and Bold is described. During zoosporogenesis, the pyrenoid undergoes regression, and the ultrastructure of this process is described in detail. The ground substance undergoes dissolution, and reticulate fibrillar structures appear as well as intruding chloroplast thylakoids. Pyrenoid-associated starch plates diminish, and quantities of starch not associated with the pyrenoid are produced. New pyrenoids appear late in the division cycle after all other major organelles associated with the motile cell have been formed. Zoospore pyrenoids develop in thylakoid-free spaces of the chloroplast which are similar to the DNA-containing regions. The new pyrenoid ground substance, which is loosely fibrillar, arises in close proximity to starch grains which may be formed in the stroma. Then the zoospore pyrenoid produces 2 hemispherical starch plates identical to those in the mature vegetative cell. Zoospore pyrenoids lack the 2 convoluted thylakoids between the starch plates and the ground substance characteristic of those in the mature vegetative cell. Instead, the thylakoids are identical to those of the chloroplast at first, and then develop into a convoluted state in the vegetative cell. Cytochemical tests for DNA, RNA, and protein were made for the cytoplasm, nucleus, nucleolus, and pyrenoid. Conclusive evidence is presented for the presence of RNA in the cytoplasm and nucleolus, DNA in the nucleus, and protein in the pyrenoid. The tests did not conclusively demonstrate the presence or absence of DNA and RNA in the pyrenoid; however, they suggested that small amounts of both DNA and RNA may be present.     

Cytology of Thamnidium elegans link

The resting nuclei in hyphae, sporangiophores and sporangiospores of sporangia and sporangiola of Thamnidium elegans consist of a large centrals nucleolus and a shell of chromatin surrounding the nucleolus. Division of the nucleus in hyphae and sporangiospores is achieved by elongation and constriction.     

多头绒泡菌细胞核周期的电镜研究

多头绒泡菌PhysarumpolycophalumSchw的营养生长阶段为没有细胞壁的原生质团（合胞体）,内部众多的细胞核进行着同步的核内有丝分裂,本文电镜下研究了细胞核在有丝分裂周期中的结构变化。有丝分裂前期,染色质经松散改组和集缩形成染色体,核仁由中央移向边缘,并在近核膜处解体;中期核膜不消失,在核内形成纺锤体,核仁解体后的物质是不规则状散在于核内;有丝分裂后核膜的破裂处重新愈合,染色体解集缩成染色质,分散的核仁物质逐渐合并形成新的核仁。     

Vegetative nuclear structures and their mode of division inCyathus species

Vegetative nuclear division in the homokaryotic and dikaryotic hyphae ofCyathus olla Brodie,C. setosus Brodie andC. bulleri Brodie was investigated. In the homokaryotic hyphae a nucleolus develops within a globular condensed nucleus consisting of a folded up filament. As the nucleolus increases in size, the nucleus unfolds and can assume a ring, horseshoe or filament configuration. The filament duplicates and (usually when unwound from the nucleolus) divides longitudinally. Occasionally, strand separation occurs while the filament is wrapped in the form of a ring around the nucleolus. The daughter nuclei may condense before the next division. In the dikaryotic hyphae the same nuclear cycle occurs as in the homokaryons except that an extra nuclear condensation to the globular form can occur in both the clamp and tube nuclei. The division of these two nuclei is not always synchronous and, moreover, the stage of karyokinesis of the clamp nucleus is not closely synchronized with the formation of the clamp connection. A deeply stained granule is associated with the nucleus. Some granules can be observed to be connected to the nucleus by a faintly Feulgen positive thread-like structure but other granules are sessile. The granule or centriole-like body is thought to direct the nuclear unfolding process. It may divide prior to, or after nuclear division.     

Nuclear architecture and DNA location in two VAM fungi

Summary The ultrastructural organization of nuclei in Glomus versiforme and G. mosseae hyphae was examined by sampling at different times during the fungus life cycle. In young and active hyphae, the nucleus is chromocentric with dispersed chromatin and a well-developed nucleolus. On aging, and particularly during arbuscule collapse, the chromatin condenses to give a pyk-notic nucleus with blebs in the envelope and conspicuous spaces between this and the nucleoplasm. DNA location by immunogold or enzyme-gold techniques resulted in uniform labelling over the chromatin. Nuclear degeneration is mirrored by decreased gold labelling and may thus be regarded as an important parameter for evaluation of fungus viability and the ephemeral life of the arbuscule.     

NUCLEAR DIVISION IN THE DEVELOPING PYCNOSPORES OF MACROPHOMINA PHASEOLI

Nuclear behavior was studied in Giemsa-stained pycnidial material of Macrophomina phaseoli. The young pycnospore was at first uninucleate but repeated nuclear division occurred as it enlarged, and the mature spore was always multinucleate. The developing spore, therefore, provided a favorable site for observing mitosis. Noteworthy features were: (1) a metaphase characterized by a loss in stainability of the nucleolus and by the appearance of centrioles, spindle fibers and countable chromosomes; (2) a short early anaphase; (3) a long late anaphase with a broad band of interzonal fibers separating the daughter nuclei; (4) the occurrence of irregularities such as aneuploidy, chromosome bridge formation and chromosome lagging. The basic chromosome number was six. Following a study of Giemsa-stained cellophane cultures of the fungus it was concluded that the method of nuclear division in the vegetative hyphae is similar to that observed in the developing spores. Some comparisons are made with observations on nuclear division in the vegetative hyphae of other fungi.