The effect of trifluoroperazine on microtubules,nuclear division and the nuclear membranes of the ciliate Nyctotherus ovalis

Exposure of the dividing ciliate Nyctotherus ovalis to the tranquilizer trifluoroperazine (TFP; 10 M) leads to the complete disassembly of kinetochore microtubules in the metaphase micronucleus. Interpolar microtubules located underneath the micronuclear envelope at anaphase and telophase stembody microtubules are more resistant to TFP. However, stembodies of drug-exposed ciliates are much shorter than in the controls. In their centre they contain only a reduced number of widely separated microtubules, indicating that assembly of new tubules or elongation of existing microtubules at this site, which appears essential for further separation of the future daughter nuclei, is blocked by TFP. Although microtubules polymerized in the macronucleus during its elongation include a set of tubules made up of more than 13 protofilaments, comparable to the micronuclear stembody microtubules, they are much more sensitive towards drug treatment. Macronuclear tubules become completely depolymerized resulting in failure of nuclear stretching. Already elongated macronuclei can still become constricted in their centre which suggests that microtubules are not involved in this process. Disassembly and higher sensitivity of macronuclear compared with micronuclear microtubules may be explained by a different composition and behaviour of nuclear membranes towards TFP in the two types of nuclei. While the micronuclear envelope may be only partially destroyed where it is facing the macronucleus, the inner membrane of the macronuclear envelope is severely affected by drug treatment. It shows a multitude of infoldings accompanied by attachment of chromatin to it. Cytoplasmic microtubules which proved resistant to other depolymerizing drugs become partly disassembled during TFP treatment.     

Spermiogenesis in the teleost Gambusia affinis with particular reference to the role played by microtubules

Summary During nuclear elongation in spermatids of Gambusia affinis, a deep fossa is formed at the base of the nucleus in which the centriolar complex and proximal portion of the flagellum reside. To stabilize the positional relationship between the nucleus and centriolar complex, while nuclear morphogenesis is taking place, a series of microtubules develop which emanate from the centriolar complex and extend to the nuclear envelope lining the fossa. Buttressing microtubules also develop within the nuclear fossa which both originate and insert along the nuclear envelope. These appear to stabilize nuclear shape prior to the time when chromatin condensation has proceeded to the stage where it could lend structural stability to nuclear form. Microtubules develop only after specific nuclear morphogenic events have taken place. It is therefore concluded that the spermatid nucleus is capable of self-assembly involving microtubules in a supportive role in addition to stabilizing the nuclear-flagellar relationship in G. affinis.The pattern of nuclear fossa-associated microtubules in G. affinis is significantly different from that observed in other poeciliid teleosts indicating a degree of species specificity with regard to both the timing of appearance and total number of microtubules.     

The 3-dimensional fine structure of the mitotic spindle in Trypanosoma cruzi

The fine structure of nuclear division in the hemoflagellate Trypanosoma cruzi has been studied with serial sections and three-dimensional reconstructions of each divisional stage. After a preliminary stage in which the chromatin becomes dispersed, there is an equatorial stage defined by the appearance of an arranged set of ten dense plaques located about the equatorial region of the nucleus. At this stage a regular microtubular spindle is formed in the nucleus. Each plaque has a symmetrical structure formed by transverse bands and the bands are formed by tightly packed fibrillar material. The wide faces of the plaques are associated with tangential microtubules coming from the poles while the front and rear edges are free to associate with chromatin. Although structural continuity between chromatin fibers and the material of the plaques is possible, this continuity has not been proved. The equatorial spindle is formed by about 120 microtubules arranged in two sets of about 60 microtubules running from each pole to the dense plaques and divided into discrete bundles which reach a single plaque. The microtubules of each bundle may pass tangential to the wide faces of the plaque and end about 0.2 m beyond it, or they may end at the pole-facing edges of the plaque. No continuous, interpolar microtubules were observed at this stage. At the beginning of the elongational stage the dense plaques split into halves and each set of half-plaques migrates to one pole. During mid-elongational stage the pole-converging microtubules and the polar bulges disappear and microtubules become rearranged between the two sets of half-plaques. During late elongational stages, continuous microtubules run between the two sets of half-plaques and maximum nuclear elongation is attained. Chromatin remains dispersed throughout nuclear division. Two main movements have been observed in these mitotic nuclei: the migration of half-plaques to the poles and the elongation of the nucleus. Both these movements are accompanied by large changes in the architecture of the microtubular spindle and are probably dependent on microtubular function. It is concluded that the dense plaques play a kinetochore-like role and thus T. cruzi would have ten chromosomal units.     

Annulate lamellae and chromatoid bodies in the testes of a cyprinid fish (Pimephales notatus)

Summary Observations on annulate lamellae and chromatoid bodies in spermatogonia of the cyprinid fish Pimephales notatus have revealed several commonly occurring features heretofore unreported: These include (a) the presence of annulate lamellae in close association with chromatoid bodies; (b) the existence of a chromatoid band or shell between the nuclear envelope and some chromatoid bodies with connections among them; (c) the presence of annulate pore complexes in the absence of well developed membrane envelopes as well as in association with such envelopes; (d) the presence of material just outside the nucleus and contiguous with nuclear pores which is of a similar density and texture to that of the chromatoid bands and chromatoid bodies; (e) filamentous material between the cytoplasmic sides of nuclear pores and the chromatoid band, bridging a distance of approximately 1000 Å and similar threads extending a like distance between chromatoid bodies (and bands) and annulate lamellae associated with them; and (f) mitochondria closely arranged about some chromatoid bodies.     

The ultrastructure of nuclear division in a suctorian,Tokophrya infusionum

Summary Ultrastructural changes in the micro- and macronucleus throughout division were followed in synchronized cultures of the suctorian, Tokophrya infusionum. After an initial swelling, the micronucleus elongates enormously; microtubules within the micronucleus proliferate and lengthen as the micronucleus elongates. Changes in the macronucleus become visible only after micronuclear division is well underway. The chromatin bodies fuse into long chromatin strands, and the large bundles of microtubules present in the resting macronucleus break up into small groups which parallel the chromatin strands. Colchicine, which prevents reproduction in Tokophrya, seems to block division at a very early stage. The macronucleus appears the same as the resting nucleus of untreated organisms, with numerous microtubules and distinct chromatin bodies. The chromatin in the micronucleus aggregates into large clumps, however, and proliferation of microtubules does not occur.Supported by a Graduate Fellowship at The Rockefeller University.Supported by Grant A1-01407-12 USPHS and Grant A1-08989-01 USPHS.     

Meiotic cytology of Saccharomyces cerevisiae in protoplast lysates

Summary This report describes cytological features of meiosis in Saccharomyces cerevisiae prepared for electron microscopy by lysis of protoplasts or nuclei on an aqueous surface. Whereas the chromatin of cells lysed before or after meiotic prophase was widely dispersed, pachytene bivalents appeared as discrete, elongate masses of compact chromatin. These bivalents were of nearly uniform thickness; they ranged in length from about 0.6 m to 4.0 m, with a median of 1.6–1.8 m. Enzymatic digestion of chromosomal DNA removed the chromatin to reveal the underlying synaptonemal complex. The lysis of partially purified nuclei was less disruptive and thereby revealed the regular association of the telomeres with fragments of the nuclear envelope. In tetraploid cells, pachytene lysates contained quadrivalents characterized by the close apposition of chromatin masses of similar length. One or more points of intimate association appear to represent sites of exchange between pairing partners. The departure of the diploid cells from pachytene was accompanied by the renewed association of spindle microtubules with the chromosomes shortly before the diplotene chromosomes decondensed. Later, the successive meiotic divisions were identified by the appearance of a single spindle for meiosis I and of two spindles for meiosis II.     

Perinuclear organization in the heterotrich ciliateStentor coeruleus

Summary Different fixation techniques were employed to obtain satisfactory fixation of the endoplasm ofStentor coeruleus for ultrastructural investigations. The nuclei ofS. coeruleus are surrounded by a flattened fenestrated cisterna. The space between the nuclear envelope and the cisterna (= perinuclear space) is continuous with the cytoplasm via channels. The envelopes of both, micronucleus and macronucleus, are connected to the fenestrated cisterna by filamentous material. This organization accounts for the close association between micronucleus and macronucleus inStentor coeruleus. The fenestrated cisterna is compared to similar structures occurring in other organisms, and its possible function is discussed.Abbreviations fC fenestrated cisterna - FV food vacuole - km km fibers - MaNu macronucleus - MiNu micronucleus - My myonome - NE nuclear envelope - PC perinuclear cisterna - PfC pore of fenestrated cisterna - PS perinuclear cytoplasmic space - EGTA ethyleneglycol-bis-(-aminoethylether)-N,N,N,N-tetraacetic acid) - GA glutaraldehyde - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - PEG polyethylene glycol - PIPES piperazine-N,N-bis[2-ethanesulfonic acid] - PTA phosphotungstic acid     

Electron microscopic observations of the influence of different fixatives on the appearance of cellular ultrastructure

Summary The cells of the proximal convoluted tubules of the rat kidney, mouse hepatic parenchymal cells, and the juxtaglomerular cells (J. G. cells) of the afferent arteriole in rabbit kidney served as test tissues for a study of the modifications of structure produced by 14 different fixation procedures using osmium tetroxide, a chrome-osmium solution, glutaraldehyde, and formaldehyde as fixatives. The fixative solutions containing various buffers were used either alone (osmium tetroxide-containing compounds) or in various combinations (aldehyde fixation with postfixation in osmium tetroxide). The most conspicuous differences in appearance following different fixation procedures were noted in the cytosomes of renal proximal tubular cells and the granules in the J. G. cells. However, virtually all cytoplasmic organelles showed some modification of structure with different fixatives. The evidence indicated that the chemical composition of the buffer used with OsO₄ was an important factor which particularly affected the density of the cytosomal matrix in renal proximal tubular and J. G. cells. The density of the matrix of the cytosomes was, however, also influenced by the fixative itself as indicated by studies of aldehyde-fixed tissues. With these fixatives the ultrastructural appearance was not modified by the buffer. Clumping of nuclear chromatin along the nuclear membrane and around the nucleolus occurred following fixation in aldehyde and Dalton's chrome-osmium solution, whereas the chromatin was evenly distributed in the nucleus when buffered osmium tetroxide was utilized for fixation. A specific reaction of dichromate with the granule of the J. G. cells seemed to take place rendering these granules electron opaque, thereby facilitating their identification in the light and electron microscope. The findings were discussed with particular attention to the interaction of fixatives and buffers with various tissue components.Supported by grants from the Board of Swedish Life Insurance Companies, the Stiftelsen Therese och Johan Anderssons Minne, and grant No. AM-7919 from the National Institutes of Health, Bethesda, Maryland (USA).     

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.     

Aberrant nuclear migration and microtubule arrangement in a defect mutant cell ofMicrasterias thomasiana

Summary Nuclear migration and the spatial arrangement of the participating microtubules are studied inMicrasterias thomasiana and in the defect mutant cellMicrasterias thomasiana f. uniradiata.In both of these cell types the two microtubule systems, the posttelophase system of MT (PTS) and the isthmus system of MT (IS)—which are known to be involved in nuclear migration and anchoring from earlier studies onMicrasterias denticulata—are present in the vicinity of the nucleus. In the mutant cell, however, the orientation of these two MT systems as well as their MT arrangement differ from those in the normalMicrasterias cells. Nuclear migration in the mutant is characterized by a turn of the nucleus and the associated PTS around one of the isthmus invaginations of the cell while in the normalMicrasterias cells it occurs as a straight-lined motion along the longitudinal axis of the cell.The results indicate that the reduction of cell pattern inMicrasterias caused by mutation is attended by a disoriented establishment of the cytoskeleton involved in nuclear migration. From comparison of the nuclear behavior and the MT arrangement in the mutant with that of the normalMicrasterias cells further information on the mechanism of nuclear migration inMicrasterias is obtained. It is suggested that interactions between the microtubule center (MC), the nuclear envelope and areas of the plasma membrane are functional in the formation, orientation and localization of the nucleus associated microtubule-microfilament complex.     

The cytology of phytophthora infestans

Summary Phytophthora infestans has three kinds of somatic nuclei: an oval shaped nucleus (approx. 3.1×2.7 ) which stains diffusely except for a crescent shaped Feulgen positive cap which stains intensely; a granular nucleus whose contents are organized into a fairly constant number of stained bodies, and, a deeply staining condensed nucleus. The capped nucleus is thought to be metabolic or resting and the granular nucleus is thought to be dividing as it is most commonly found in hyphal tips. Attenuated forms of all three kinds of nuclei are found.Nuclear division is mitotic and intranuclear. Eight—ten chromosomes are seen at metaphase.Sporangia have a mean of 6.3 nuclei which is constant for age and strain of culture. Sporangia become multinucleate as a result of nuclear migration and not by division in the developing sporangium. Zoospores are usually uninucleate.The nuclear cap is persistent throughout nuclear division when it also divides. It is associated with flagella production and nuclear migration and has some of the properties of a blepharoplast.     

Development of the resting sporangia ofSynchytrium endobioticum,the causal agent of potato wart disease

Summary An ultrastructural study of the development of the resting sporangium ofSynchytrium endobioticum (Schilb.) Perc. infecting potato cells is presented. The resting sporangium is found to have a single large, centrally placed nucleus with a prominent nucleolus through its entirein situ development. The cytoplasmic organization of the resting sporangium is further characterized by numerous membrane-bound lipid bodies and osmiophilic bodies. The latter have a characteristic sieve-like appearance, probably because certain storage components have been extracted during preparation for electron microscopy. Because of the similar location and appearance of these osmiophilic bodies it is suggested that they are identical to what has earlier (based on light microscopy) been described as chromatin granules; and the ultrastructural studies presented here show that nucleolar discharge which was described from light microscopic observations as leading to chromatin granules in the cytoplasm, and finally forming the nuclei of the zoospores (bally 1912,curtis 1921,percival 1910) simply does not occur.The appearance of dense fibrillar-like structures on the sporangial surface at an early stage of resting sporangium development ultrastructurally distinguishes the resting sporangium from the zoosporangium. The development of the layered portion of the thick sporangial wall is shown to be due to the fusion of vacuoles containing pre-made wall fibrils with the cell membrane. It is suggested that the inner compact wall layer which is essentially substructureless is formed by the membrane itself.The characteristic wings of the matureS. endobioticum resting sporangium originate from the potato host cell wall. Remnants of host cell organelles in the outermost layer of the resting sporangium wall show that degradation of the host cell cytoplasm contributes to wall formation of the parasite.     

Holokinetic composite chromosomes with “diffuse” kinetochores in the micronuclear mitosis of a heterotrichous ciliate

During micronuclear mitosis of the heterotrichous ciliate Nyctotherus ovalis Leidy rod-shaped composite chromosomes are formed by lateral association of telokinetic chromosomes. The formation of these composite chromosomes seems to be a highly ordered process since only nuclei with either 18 or 24 such chromosomes can be observed, and nuclei with the same chromosome number show a similar length distribution of their chromosomes. Further, these data indicate that we examined two otherwise indistinguishable races. During metaphase the composite chromosomes become arranged in the spindle equator in a holokinetic fashion, their entire poleward surfaces being covered by kinetochore material. These diffuse kinetochores have a trilaminar appearance comparable to those of monokinetic chromosomes. Their electron density after employing Bernhard's procedure revealed the same ribonucleoprotein distribution as reported for the localized kinetochores formed during the extranuclear mitosis in other cells. During early anaphase the outer kinetochore layer remains continuous while the individual chromosomes in the composite group show a tendency to separate leaving chromatin-free spaces of about 40 nm diameter. Kinetochore microtubules which are still anchored in the outer kinetochore layer seem to elongate and to extend into the interpolar spindle region predominantly through these holes in the chromatin. These observations suggest a like polarity of kinetochore and interpolar microtubules in the polar spindle region while microtubules in the interpolar space seem to interdigitate in an antiparallel fashion. The activity of the kinetochore to act as a microtubule-organizing center (MTOC) seems to be modulated by the chromatin underlying the outer kinetochore layer which may prevent further outgrowth of kinetochore microtubules.     

Changes in density of chromatin in the meristematic cells ofSinapis alba during transition to flowering

Summary Changes in the density of nuclear chromatin in the shoot apical meristem ofSinapis alba L. during floral transition (floral evocation) are described using Feulgen-stained 2 m thick semi-thin sections and scanning cytophotometric techniques. In both G1 and G2 nuclei the chromatin becomes less heterogeneous and less dense in evoked meristems compared to vegetative meristems. When chromatin is resolved into two fractions the dispersed fraction increases relative to the condensed fraction at evocation. This decondensation process occurs earlier in G1 than in G 2 nuclei. These chromatin changes are presumably closely related to the dramatic stimulation of biosynthetic activity and cell division during floral transition.     

Die Intravitale Karyorrhexis Der Exokrinen Pankreaszelle im Elektronenmikroskopischen Bild

Zusammenfassung Die intravitale Karyorrhexig wird am exokrinen Pankreas der Maus nach Osmium- und Formalinfixierung licht- und elektronenmikroskopisch untersucht. Im Verlaufe der Karyorrhexis kommt es zu einer Trennung des Karyoplasmas in 'Chromatin und 'Karyolymphe (Interchromatin-Substanz). In fortgeschrittenen Stadien ist das Bild solcher Zellkerne — im Gegensatz zu normalen Intermitosekernen — nach beiden Fixierungsmethoden fast identisch. Das Chromatin ist in dichten, membranständigen Kappen konzentriert. Der übrige Kernraum wird — abgesehen vom Nukleolus — von der hellen Karyolymphe ausgefüllt. In ihrem Bereich treten die sog. Interchromatingranula (200–250 Å), einzeln oder in dichten Haufen, meist deutlich hervor. Der Nukleolus, dessen Feinstruktur nicht auffallend verändert ist, liegt entweder frei oder den Chromatinkappen unmittelbar an. Die Kernhülle ist bei fortgeschrittener Karyoplasmaentmischung unversehrt oder über kürzere oder längere Strecken geschwunden. Im Endstadium der Karyorrhexis sind mehrere, von Kernmembranfragmenten unvollständig begrenzte Chromatinbrocken wahllos im Zelleib verstreut. Die cytoplasmatischen Strukturen können auch bei ausgeprägten Kernveränderungen noch weitgehend normal aussehen.Die karyorrhektischen Kernveränderungen werden als Folge einer 'Entmischung des Karyoplasmas gedeutet, für die eine Dehydratation der DNS-tragenden Chromosomenstrukturen verantwortlich gemacht wird. Auch das Sichtbarwerden und das Verklumpen der 'Interchromatingranula wird auf eine Dehydratation zurückgeführt.

---

Summary The intravital caryorrhexis in the exocrine pancreas of the mouse was studied by means of light- and electron microscopy after fixation with osmium and formaldehyde. During caryorrhexis the caryoplasm segregates into chromatin and caryolymphe (interchromatinic substance). In contrast to normal intermitotic nuclei both fixations result in a very similar picture of the typical caryorrhectic nuclei. The chromatin is concentrated in dense caps associated with the nuclear envelope. Except those dense caps and apart from the nucleolus the whole nucleus is occupied by the light caryolymphe. In this area the so-called interchromatinic granules (200–250 Å) become clearly visible, isolated or in dense clumps. The nucleolus, the fine structure of which has not remarkably changed, can be found either isolated or in touch with the chromatin caps. During advanced segregation of the caryoplasm the nuclear envelope was found to be either unimpaired or had disappeared for variable lenghths. In the final stage of caryorrhexis several chromatin clumps — partly confined by fragments of the nuclear envelope — are distributed irregularly within the cell. Even in the case of pronounced nuclear changes the cytoplasmic structures may appear almost unaffected.It is assumed that the nuclear changes during caryorrhexis are due to a segregation of the caryoplasm, caused by dehydration of the DNA-carrying chromosome fibrils. Also dehydration is made responsible for the appearance and clumping of the interchromatinic granules.

     

Radiation induced formation of giant cells inSaccharomyces uvarum III: Effect of X-rays on nuclear division

Summary Spindle formation and nuclear division of budding and irradiated yeast cells (Saccharomyces uvarum) was investigated by fluorescence microscopy of protoplasted cells. Protoplasts were treated with antitubulin antibodies and DAPI, a fluorescent dye staining DNA. In budding yeast cells, duplication of spindle pole bodies as well as formation of complete 1-µm spindles and elongated 8-µm spindles were documented. In X-irradiated cells, spindle pole bodies were duplicated as well, forming the complete 1-µm spindle. Nuclei of giant cells have lost the elongation ability and remain in a normal G₂-phase state, thus preventing nuclear as well as cellular division.     

Molecular and cytological characteristics of nuclear DNA and chromatin for angiosperm systematics: Basic data forHelianthus annuus (Asteraceae)

As a contribution for the study of systematic and evolutionary relationships it is suggested to analyze nuclear DNA and chromatin by means of CsCl ultracentrifugation, thermal denaturation and renaturation, scanning densitometry, and (ultra)structural analyses. Relevant data have been obtained forHelianthus annuus as a first example.The 2C DNA content of four cultivars ofHelianthus annuus L. was calibrated by comparative measurement withAllium cepa nuclei using a scanning densitometer in on-line operation with a computer. Significant infraspecific variation could be detected: cvar. Amerikanische Riesen displayed 6.1 pg, cvar. Gefüllte Vielblütige 9.9 pg, cvar. Russian Mammoth 8.9 pg, and a Heidelberg strain 8.7 pg.The buoyant density in neutral CsCl was determined for cvar. Amerikanische Riesen to be 1.695 g · cm^–3; this corresponds to an average GC content of 35.1%. Thermal denaturation revealed a melting temperature of 86.4°C. Derivative thermal denaturation profiles led to the detection of several distinct DNA fractions.The species-specific nuclear structure is of the chromonematic type, but in differentiated cells the chromatin fibers may be more decondensed so that a chromomere-interchromomere structure appears. The heterochromatin constitutes an average of 4.5% of the total genome. Chromatin ultrastructure is characterized by a diffuse distribution of chromatin threads and patches. Nucleosomes of 110 Å diameter can be recognized.The data are discussed (a) in relation to findings on DNA variation in other plants, (b) in relation to the systematic usefulness and further characterization of nuclear DNA and chromatin, and (c) in relation to tissue-specific and functional variation of the species-specific chromatin structure.     

Reorganization of microtubules in the amitotically dividing macronucleus of tetrahymena

We developed a modified immunofluorescence protocol that permitted visualization of microtubules inside the macronucleus of the ciliate Tetrahymena. Although the amitotically dividing macronucleus lacks a spindle, an elaborate system of microtubules is assembled inside the macronucleus and between the macronucleus and the cortex. Microtubules could not be detected inside the interphase macronuclei. The early stage of macronuclear division was associated with the assembly of short macronuclear microtubules that localized randomly. The intramacronuclear microtubules were subsequently organized in a radial manner. During elongation of the macronucleus, the distribution of macronuclear microtubules changed from radial to parallel. During constriction of the macronucleus, dense and tangled macronuclear microtubules were detected at the region of nuclear constriction. In the cytosol, microtubules were linking the macronucleus and cell cortex. During recovery after drug-induced depolymerization, microtubules reassembled at multiple foci inside the macronucleus in close proximity to the chromatin. We propose that these microtubules play roles in chromatin partitioning, macronuclear constriction, and positioning of the macronucleus in relation to the cell cortex.     

Accumulation of β-tubulin-containing fibres in the cortical domain ofSaccharomyces cerevisiae spheroplasts

Summary The distribution of microtubules inSaccharomyces cerevisiae was studied with the monoclonal antibody (mab) TU-14 against -tubulin. Immunoblotting and immunoprecipitation experiments with a strain overexpressing Tub2p confirmed that the mab TU-14 specifically recognized Tub2p. By immunofluorescence microscopy, the mab TU-14 attached to all known tubulin structures labelled with the standard polyclonal anti--tubulin antibody 206-1. In addition, the mab TU-14 revealed cortical patches in wild-type cells and an abundant network of fibres in the cortex of spheroplasts cultivated in nutrient medium. These cortical fibres seemed to be specific to spheroplasts and suggest that the accumulated Tub2p is predominantly associated with the plasma membrane.     

Transformation of the Golgi apparatus in the cell cycle of a green alga,Micrasterias americana

Summary Transformation of the Golgi apparatus in the stages of the cell cycle ofMicrasterias americana was investigated with an electron microscope. In the resting cell, dictyosomes consisted of eleven cisternae, the distal-most cisterna of which was partially network-shaped. During the developmental stages of the new half cell followed by nuclear division, dictyosomes produced dark vesicles and large vesicles at the peripheries of the distal cisternae, thus diminishing the diameter of the distal cisternae and their numbers. Finally, dictyosomes with six or seven cisternae of small diameter were found when the new half cell reached to full size as a mother half cell. At this stage, the small dictyosomes produced flat vesicles. Thereafter, dictyosomes recovered the size and number of their constituent cisternae, being supplied a membrane and substrate from the primary vesicles. Lysosomes divided the dictyosomes in two, and these divided dictyosomes seemed to regenerate in one case and to disorganize in another. The occurrence of large vesicles was also confirmed using the negative staining method in growing cells.