THE ULTRASTRUCTURE OF CRUCIFORM NUCLEAR DIVISION IN SOROSPHAERA VERONICAE (PLASMODIOPHOROMYCETE)

Vegetative nuclear divisions in cystosoral Plasmodia from the shoot system of Sorosphaera veronicae Schroeter were studied with standard transmission electron microscopy. Each metaphase nucleus forms a cruciform configuration as the persistent nucleolus elongates perpendicularly to chromatin aligned on the equatorial plate. The nuclear envelope remains intact during metaphase and anaphase. Each spindle pole consists of a fenestrated nuclear envelope with an exteriorly situated centriole and closely associated endoplasmic reticulum. Intranuclear membranous vesicles occur within metaphase and anaphase nuclei and are closely associated with chromatin and nuclear envelope. Microtubules pass from centrioles into the nucleus and are also attached to chromatin at kinetochores.     

The ultrastructure of mitosis during sporangiogenesis inWoronina pythii (Plasmodiophoromycetes)

Summary Mitotic divisions during sporangiogenous plasmodial cleavage inWoronina pythii were studied with transmission electron microscopy. We conclude that these nuclear divisions (e.g., transitional nuclear division, and sporangial mitoses) share basic similarities with the cruciform nuclear divisions inW. pythii and other plasmo-diophoraceous taxa. The major distinction appeared to be the absence of nucleoli during sporangial mitosis and the presence of nucleoli during cruciform nuclear division. The similarities were especially evident with regard to nuclear envelope breakdown and reformation. The mitotic divisions during formation of sporangia were centric, and closed with polar fenestrae, and characterized by the formation of intranuclear membranous vesicles. During metaphase, anaphase, and telophase, these vesicles appeard to bleb from the inner membrane of the original nuclear envelope and appeared to coalesce on the surface of the separating chromatin masses. By late telophase, the formation of new daughter nuclear envelopes was complete, and original nuclear envelope was fragmented. New observation pertinent to the mechanisms of mitosis in thePlasmodiophoromycetes include a evidence for the incorporation of membrane fragments of the original nuclear envelope into new daughter nuclear envelopes, and b the change in orientation of paired centrioles during sporangial mitosis.     

The ultrastructure of mitosis in myxamoebae and plasmodia of Physarum flavicomum

Electron microscopy of glutaraldehyde-osmium-fixed samples of haploid myxamoebae and diploid plasmodia of the myxomycete Physarum flavicomum Berk. reveal dissimilar spindle apparatus during mitosis in the two cell types. Myxamoebae exhibit an astral type of mitosis with centrioles at the poles and nuclear envelope breakdown during prophase. Plasmodial nuclei lack centrioles at mitosis and have an intranuclear spindle, with nuclear envelope persisting during the entire division. Coated vesicles are noted during prophase and telophase in myxamoebae and their role in spindle formation and dispersion is suggested.     

Reformation of the nuclear envelope in melanophores during recovery from a hormone plus puromycin treatment

Previous experiments have shown that treatment of the melanophores of Pachymedusa (Agalychnis) dacnicolor with Melanophore-Stimulating Hormone (MSH) + puromycin causes the nuclear envelope to breakdown leading to the formation of discontinuous vesicles and the hyperdispersion of chromatin. We show here that these cells recover, reform their nuclear envelopes, and recondense their chromatin, both in the presence and in the absence of actinomycin D (actD). After recovery, these cells respond to MSH by melanosome dispersion. From these results, the following conclusions or observations are drawn:

1. 1, Reformation of nuclear envelope does not require that the chromatin be condensed into chromosomes as in mitosis.

2. 2, The new nuclear envelope is derived primarily from reutilization of the membrane vesicles produced during nuclear envelope breakdown, somewhat similar to mitosis. There may also be contributions from other membranous organelles.

3. 3, The hyperdispersed chromatin appears not to be subject to extensive attack by endogenous nucleases as the recovered cells are of good ultrastructure and can respond tropically to MSH.

4. 4, The presence of actD appears not to prevent the conversion of the hyperdispersed chromatin into the normal pattern.

     

Process of nuclear envelope reduction in spermiogenesis of a mosquito,Culex tigripes

When the Culex tigripes spermatid begins to elongate, the nucleus exhibits on its surface invaginations of the nuclear envelope. These invaginations have a uniform diameter of 0.3 μm. They separate from the envelope of the nucleus and form spherical intranuclear vesicles. In the old spermatids these vesicles are imprisoned in the condensed chromatin. The spermatozoon also possesses these vesicles which are then ovoid in shape. This process of vesiculation permits the diminution of the surface of the nucleus when it decreases in volume during spermiogenesis. © 1993 Wiley-Liss, Inc.     

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.     

Formation of the nuclear envelope during mitotic anaphase inSpirogyra

The formation of the nuclear envelope in the mitosis ofSpirogyra was studied with an electron microscope. The nuclear envelope was disrupted around the spindle equator in the metaphase. Many small vesicles were observed in the metaphase spindle. These vesicles surrounded the masses of chromosomes and nucleolar substance in the early anaphase, and they fused with each other to form daughter nuclear envelopes during the early anaphase. The formation of new envelopes from small vesicles at such an early mitotic anaphase is reported here for the first time. The possible origin of these vesicles is also discussed.     

A UNIQUE MITOTIC VARIATION IN THE MARINE DINOFLAGELLATE OXYRRHIS MARINA (PYRROPHYTA)1

Mitosis is described in the flagellate Oxyrrhis marina Dujardin and is compared in related genera. Dense plaques develop in the nuclear envelope at prophase and give rise to an intranuclear spindle. Some of the microtubules associate with the chromosomes while others extend across the nucleus. The basal bodies migrate toward the poles early in division and retain a position lateral to the nuclear poles throughout mitosis. Microtubules are not present between the nucleus and the basal bodies. The nucleolus is persistent and elongates throughout anaphase and telophase. Chromosomal separation is accomplished by sliding of non-chromosomal microtubules and by elongation of the nuclear envelope rather than by shortening of the spindle microtubules. The nuclear envelope begins to constrict in the center early in anaphase. Continued constriction of the envelope and elongation of the nucleus leads to the formation of a dumbbell-shaped nucleus by late telophase. Mitosis culminates by the constriction of the nucleus into two daughter nuclei. The taxonomic position of Oxyrrhis marina is discussed in light of these findings.     

Ultrastructural study on pronuclear development in fertilized eggs from goldfish, Carassius auratus

The formation of male and female pronuclei in physiologically monospermic fertilized eggs of the goldfish, Carassius auratus , has been investigated with transmission electron microscopy. Ultrastructural observations show that at 26°C the transformation of the sperm nucleus takes place very quickly. The sperm nuclear envelope degenerates and is replaced by a large number of smooth surface vesicles 1 min post-insemination. Concomitantly, most of the condensed sperm chromatin is dispersed and is surrounded by vesicles. Dispersion of the chromatin is followed by the fusion of vesicles and the formation of a new bilaminar pronuclear envelope. Within 5–10 min post-insemination, a spheroid male pronucleus with intranuclear annulate lamellae is produced. The formation of a female pronucleus is slightly different to that of the male pronucleus. The dispersing chromatin of the egg is divided into many groups, most of which are surrounded by multilaminar envelopes 5 min post-insemination. An ellipsoid female pronucleus with a continuous bilaminar pronuclear envelope and intranuclear annulate lamellae is formed 15 min post-insemination. Subsequently, the two pronuclei migrate towards one another. When the fully developed male and female pronuclei are located in the center of the blastodisc, each changes itself into a saccular complex 25 min post-insemination.     

Intranuclear annulate lamellae in oocytes of the tunicate,Styela partita

Summary Intranuclear annulate lamellae have been observed with the electron microscope in oocytes of the tunicate, Styela partita. Morphological evidence suggests that the annulate lamellae may arise by a specialized fusion process of individual vesicles. Intranuclear vesicles appear to be formed, in time, before differentiated annulate lamellae. It is also suggested that the position and structure of an annulus is in large part determined by the fusion of the vesicles. An annulus may be present as soon as two vesicles have completed their fusion process. Finally, it is again suggested on the basis of morphological evidence that the intranuclear vesicles are derived by the blebbing activity of the inner layer of the nuclear envelope.This investigation was supported by grants (RG-9229, 9230) from the National Institutes of Health, Public Health Service. The electron microscope facilities used were also supported by a grant (GM-05479) from the National Institutes of Health to Professor H. W. Beams.     

Spindle membranes and calcium sequestration during meiosis ofDysdercus intermedius (Heteroptera)

The fate of intracellular membranes stained by the osmium ferricyanide (OsFeCN) procedure was followed from premeiotic interphase to interkinesis inDysdercus intermedius. During diakinesis the centrioles forming primary cilia attach temporarily with their proximal ends to the nuclear envelope which is stretched from pole to pole. Breakdown of the nuclear envelope is preceded by deep indentations with microtubules from growing asters. Vesicles of smooth endoplasmic reticulum which accumulate gradually in the course of prophase contribute to the ensheathment of the chromosomes with membranes. When the nuclear envelope breaks down, the polar parts of the formerly perinuclear membranes follow the ingrowth of the spindle microtubules towards the cell equator where the seven bivalents are arranged in a circle with the X₁X₂ sex chromosomes in the centre. The metaphase I spindle thus contains longitudinally oriented membranes between the poles, membranous envelopes around all chromosomes and radial connections from the autosomes to the sex chromosomes in the centre. At anaphase the homologues leave their common sheath and a microtubular stembody surrounded by membranes appears between the receding dyads. In the interkinetic nucleus the gonosomes are separated from the autosomes by a common membranous sheath which may be instrumental in their joint assignment to only one pole in the second meiotic division. Calcium sequestering sites visualized by oxalate precipitation are the Golgi lamellae and vesicles derived from them that surround the whole spindle body.     

The Origin and Fate of Annulate Lamellae in Maturing Sand Dollar Eggs

Electron micrograph evidence is presented that the nuclear envelope of the mature ovum of Dendraster excentricus is implicated in a proliferation of what appear as nuclear envelope replicas in the cytoplasm. The proliferation is associated with intranuclear vesicles which apparently coalesce to form comparatively simple replicas of the nuclear envelope closely applied to the inside of the nuclear envelope. The envelope itself may become disorganized at the time when fully formed annulate lamellae appear on the cytoplasmic side and parallel with it. The concept of interconvertibility of general cytoplasmic vesicles with most of the membrane systems of the cytoplasm is presented. The structure of the annuli in the annulate lamellae is shown to include small spheres or vesicles of variable size embedded in a dense matrix. Dense particles which are about 150 A in diameter are often found closely associated with annulate lamellae in the cytoplasm. Similar structures in other echinoderm eggs are basophilic. In this species, unlike other published examples, the association apparently takes place in the cytoplasm only after the lamellae have separated from the nucleus. If 150 A particles are synthesized by annulate lamellae, as their close physical relationship suggests, then in this species at least the necessary synthetic mechanisms and specificity must reside in the structure of annulate lamellae.     

Etude ultrastructurale et cytochimique de la formation des inclusions intra-nucléaires dans les ovocytes de l'Annélide Nereis diversicolor O. F. Müller

Résumé Chez N. diversicolor, les ovocytes proches de la maturitée sexuelle ou ayant évolués en l'absence d'hormone cérébrale renferment dans leur nucléoplasme des vésicules localisées à proximité de l'enveloppe nucléaire. Ces vésicules contiennent un nombre variable de granules denses élaborés par un processus d'invagination de la paroi vésiculaire.Ces inclusions intra-nucléaires semblent résulter de l'évolution de petites vésicules applaties, accolées à la membrane nucléaire interne. Dans le cas de l'ovogenèse expérimentale, ces petites vésicules peuvent s'associer pour former des lamelles annelées intra-nucléaires. Ces dernières sont fréquemment en relation avec les vésicules à grains denses et semblent jouer un rôle dans leur élaboration.L'action de la pepsine sur des ultra-coupes d'ovocytes inclus au GMA entraîne une forte diminution de la densité du contenu des granules intra-vésiculaires qui apparaissent constitués essentiellement de protéines.

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Ultrastructural and cytochemical study of the formation of intranuclear inclusions in the oocytes of the annelid Nereis diversicolor O. F. Müller

Summary In Nereis diversicolor, oocytes close to or having reached maturity in the absence of brain hormone, contain in their nucleoplasm vesicles that are located in close proximity to the nuclear envelope. These vesicles contain a variable quantity of dense granules which are derived from the vesicular wall by a process of invagination.The intranuclear inclusions seem to be derived from small flattened vesicles located close to the inner membrane of the nuclear envelope. In the case of experimentally induced oogenesis these small vesicles may join to form intranuclear annulate lamellae. The latter are frequently affiliated with the vesicles containing dense granules and seem to play a role in their formation.The effect of pepsin, applied to ultrathin sections of oocytes embedded in glycol-methacrylate, is a pronounced reduction in the density of the contents of the intravesicular granules which, therefore, appear to consist essentially of protein.

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Remerciements. Je remercie le Service de Microscopie Electronique de l'Institut Pasteur de Lille (Directeur: Prof. Vivier) pour l'aide apportée à la réalisation des inclusions de GMA, et M. Himpens, dessinateur du Laboratoire de Biologie Animale de la Faculté des Sciences, pour le tracé de la Fig. 12.     

Karyomeres in early cleavage embryos of ophryotrocha labronica lagreca and bacci

Summary Karyomeres or chromosome vesicles occur regularly at all cell divisions in cleavage embryos ofOphryotrocha labronica up to the 16-cell stage. They are formed as separate units, containing one or several nucleolus-like bodies (NLB) as well as intranuclear annulate lamellae (IAL), but coalesce later into a compound nucleus, in connection with copious blebbing and simultaneous appearance of cytoplasmic annulate lamellae (CAL). Labelling of the early embryos with³H-thymidine revealed marked localization of the synthesized DNA to the karyomere envelope region, whereas³H-uridine incorporation, indicating RNA synthesis, was sparse and notably absent in the NLB. On the other hand the latter structure like the envelopes preferentially incorporated³H-myoinositol, and displayed considerable labelling with³H-leucine. The mechanism and general significance of karyomere formation is discussed with particular attention to the NLB and their possible involvement in nuclear membrane formation.This work has been supported by the Swedish Natural Science Research Council and Kungliga Fysiografiska Sällskapet, Lund.The excellent technical assistance of Mrs Annagreta Petersen and Mrs Lena Olsson is gratefully acknowledged.     

Formation of the Cyst Wall of the Ciliate Colpoda steinii

After a thin membranous envelope surrounding the cell body and cilia of Colpoda steinii has been formed, the main mass of the proteinaceous cyst wall is deposited without exocytosis. It can be composed of two layers, the denser and wrinkled ectocyst and the smooth-walled endocyst; however, the ectocyst may be missing. Evidence is presented that ecto- and endocyst are formed from vesicles derived from abundant rough endoplasmic reticulum which appears at the time of wall formation. The cilia are retained and become embedded in the peripheral cytoplasm. Synthesis of RNA and protein is required as actinomycin C and cycloheximide block cyst formation. Calcium is required during a sensitive phase prior to encystment.     

Brush-border formation in the midgut of an insect,Calliphora erythrocephala meigen

Summary The embryonic development of the brush-border of anterior midgut cells of Calliphora was studied by electron microscopy. Dense surface-forming vesicles, as described by Bonneville (1970), are found prior to microvillus formation. These dense vesicles provide membranous and coating material for the moulding of the microvilli. The number of dense vesicles increases rapidly to a maximum just before brush-border formation, after which it decreases very rapidly, accompanied by an increase in the number of microvilli. Formation of microvilli proceeds in essentially the same way as in Xenopus. First, some of the vesicles fuse with the apical cell membrane, resulting in an increase of the cell surface, part of which is coated with filamentous material deriving from the dense vesicles. This in turn leads to bulging, and short irregular microvilli appear. These are erected and elongated.Prefabricated tubular elements are believed to play a part in this erection and elongation, probably due to the unwinding of spirally coiled strands.Microvillus formation proper lasts 2 to 3 hours in Calliphora. Almost the entire amount of membranous and coating material is prefabricated prior to the formation of microvilli.     

The spermatozoa of ascidians: Acrosome and nuclear envelope

Summary The spermatozoon of Ascidia callosa has a head with a wedge-shaped tip. Between the nuclear envelope and the plasmalemma, at the tip of the head, there are one or two previously undescribed vesicles, 45 to 55 nm in diameter. These vesicles have the characteristics of an acrosome. Their role in the process of fertilization has not been determined. Ultrastructural studies of sperm activation are needed, but claims that the spermatozoa of ascidians do not have an acrosome should be reconsidered.Behind the tip of the sperm there are pores in the nuclear envelope. This part of the envelope also contains a dense band of amorphous material that may have a supportive function. A nearly identical structure, associated with pores has been found in the spermatozoon of Boltenia villosa. An analysis of the nuclear envelope of Ascidia callosa indicates that the same structure has previously been misinterpreted as an acrosome in the spermatozoon of Ascidia nigra.     

Nuclear reconstitution of demembranatedOrychophragmus violaceus sperm inXenopus laevis egg extracts

The cell-free extracts from animalXenopus laevis egg could induce chromatin decondensation and pronuclear formation from demembranated plant (Orychophragmus violaceu) sperm. The demembranatedOrychophragmus violaceus sperm began to swell in 30 min incubation, and then were gradually decondensed. The reassembly of nuclear envelope in the reconstituted nuclei had been visualized by means of electron microscopy and fluorescent microscopy. Membrane vesicles fused to form the double envelope around the periphery of the decondensed chromatin. The morphology of the newly formed nucleus, with a double membrane, was similar to those nuclei after fertilization. Transmission electron microscope micrograph of the whole mount prepared nuclear matrix-lamina showed the reconstituted nucleus to be filled with a dense network.     

Division spindle and centrosomal plaques during mitosis and meiosis in some Ascomycetes

The behaviour of the division spindle and centrosomal plaques is described in four species of Ascomycetes (Ascobolus immersus, Ascobolus stercorarius, Podospora anserina and Podospora setosa) studied by light and electron microscopy. Two unique features of the kinetical apparatus were observed: presence of centrosomal plaques and intranuclear location of the spindle. In all types of mitoses (mycelium, crosier and postmeiotical mitosis) the apparatus is structurally identical to that found in meiosis. The centrosomal plaques, present in all divisions, are always contiguous with the nuclear envelope and never show centrioles similar to those commonly found in Metazoa and Protozoa. During metaphase and anaphase the plaque is constituted of two zones situated on each side of the nuclear envelope: an electron opaque outer zone and inner one less opaque in which most of the microtubules end. In Podospora the outer zone appears in sections as consisting of two dark layers separated by a clear one. Two dispositions of plaques are possible: either they are entirely contiguous with the nuclear envelope (Ascobolus) or only partially so, the remainder being perpendicular to the nuclear envelope (Podospora). — The localisation of the plaques in the ascus was determined by light and electron microscopy. The nuclear envelope was shown to remain intact during division. It was possible to observe that the sporal wall of each spore originated from the same unique double membrane formed in the ascus during the meiotic second division and postmeiotical mitosis. This fact is of genetical interest for the study of morphological and physiological characters of the spores.     

FINE STRUCTURE OF THE DIATOM AMPHIPLEURA PELLUCIDA. II. CYTOPLASMIC FINE STRUCTURE AND FRUSTULE FORMATION

The general arrangement of cytoplasmic organelles in Amphipleura pellucida Kutz. is similar to that in other naviculoid diatoms. The chromatophores are parietal with a single, non-membrane-limited, pyrenoid. The pyrenoid is crossed by several double-disc lamellar bands which are occasionally interrupted by less dense areas containing convoluted tubules. Similar areas also interrupt the three-disc bands of the chromatophores. The nucleus is irregular in shape. The outer membrane of the porous nuclear envelope outfolds around the chromatophore. A perinuclear dictyosome complex is present. Amorphous dense bodies are formed in elaborations of the dictyosomes. Vesicles, both with and without dense inclusions, are formed by the dictyosomes during cell division and a role is suggested for these vesicles in both cytokinesis and frustule development. The first evidence of frustule formation is the deposition of the siliceous median rib within a membranous sac. This sac expands laterally to form the silica deposition vesicle which appears to serve as a mold for the formation of the valve. After the valve is formed, the membranes and the small amount of cytoplasm external to it are sloughed off.