The Nuclear Apparatus of the Ditransversal Ciliate Homalozoon vermiculare (Ciliophora,Rhabdophora) during Interphase and Division. I. The Macronucleus1

ABSTRACT. The nuclear apparatus of Homalozoon vermiculare consists of a single moniliform macronucleus and about 25 micronuclei. The number of macronuclear segments depends (i) on the number of divisions of individual segments during the interphase and (ii) on the number of segments that arise prior to cytokinesis from the (temporary) filiform macronucleus. Precytokinetic changes of the macronucleus involve the fusion of individual segments followed by contraction and subsequent elongation of the entire macronucleus. The chromatin bodies uncoil into fine fibrils during macronuclear contraction. At the time when the division furrow appears, the macronucleus starts to renodulate. The interphase segment contains a more or less reticulated chromatin body partly attached to the nuclear envelope and about 30 polymorphous nucleoli. The latter consist of the pars granulosa, the pars fibrosa, and an additional fibrillar component. The nucleoli undergo drastic changes prior to division and the granular component disappears completely during macronuclear condensation. On the average, the macronucleus contains a 3,400-fold amount of DNA compared with a haploid micronucleus, but the intraspecific differences in the DNA content of the entire macronucleus are extremely large. In contrast, DNA content and size of an individual segment of the macronucleus are precisely regulated during interphase.     

Ultrastructure of the nuclear apparatus of the infusorian Loxodes magnus. I. The macronuclei, macronuclear anlagen and the interphasic micronuclei]

The nuclear apparatus of Loxodes magnus Stokes (Holotricha) consists of numerous macronuclei which belong to the diploid type and never divide, and of numerous micronuclei. No nuclear groups exist; individual nuclei often lie in cytoplasmic islets surrounded by large lacunae of the smooth endoplasmic reticulum. Interphasic micronuclei have two-membraned envelopes with numerous pores, usually lined at the cytoplasmic side with a layer of vacuoles, channels, or flattened vesicles of the smooth endoplasmic reticulum. The chromatin of the micronuclei consists of anastomosing threads, 0.1--0.2 mum wide, between which several nucleolus-like bodies of microfibrillar structure occur. Adult macronuclei have a similar nuclear envelope and a similar system of vacuoles, channels, and flattened agranular cisternae outside it. The macronucleus contains a single large composite nucleolus with 3 or 4 fibrillar cores inside the common granular cortex. The fibrillar cores are pierced by channels containing nucleolar organizers in the form of strands of condensed chromatin. The peripheral zone of the macronucleus is filled with decondensed chromatin fibrils and contains a number of small chromocenters and several aggregates of RNP granules. No protein inclusions (spheres) have been observed in Loxodes macronuclei. The macronuclear anlagen, developing in the cycle of every cell division, show progressive decondensation of the chromosomes and formation of several nucleoli, each with its own organizer. Later on, the nucleoli fuse into a single nucleolus. The small chromocentres are the last to form.     

Observations on the Fine Structure of the Nuclear Apparatus of Blepharisma intermedium Bhandary (Ciliata: Spirotricha)

SYNOPSIS. An electron-microscope study of the macronucleus and the micronucleus of Blepharisma intermedium Bhandary has been made. Sections show that the macronucleus is bounded by a double membrane. Inside, there are two types of bodies: (a) small irregular bodies, from 0.05 to 0.2 μ in diameter, and (b) larger bodies, from 0.4 to 0.6 μ in diameter. The former are intrepreted as cut ends of long, branching filaments traversing the nuclear cavity in all directions. They correspond to the DNA filaments obtained by centrifugation and KCN action on the macronucleus. Each filament is made of fibrils aboue 150 Å thick. The large bodies correspond to the nucleoli; they also show a fibrillar structure. They offer the added interest of displaying dense particles, from 100 to 800 Å in size, whose nature and significance are obscure. The micro-nucleus has a double membrane, and the contents are divisible into an electron-dense network and a material of low density which fills the interstices of the network.     

A system of interlacunar network and thick fibrils in human hyaline cartilage

Summary A system consisting of an interlacunar network and thick fibrils was demonstrated in the matrix of human fetal and neonatal hyaline cartilage, using an osmium-ferrocyanide mixture as a second fixative. The network appeared as irregular strands consisting of hyaluronidase-sensitive, amorphous and fine fibrillar material. The thick fibrils measured 75–125 μm in diameter, each appearing to consist of several collagen fibrils twisted into a cable and cemented by dense amorphous material. Strands of the network were seen to cross and focally distort the thick fibrils, suggesting that the strands exert some tensile forces on the thick fibrils. During the first year of life the network rapidly became undemonstrable, but the thick fibrils persisted into adulthood. This system of interlacunar network and thick fibrils appears to form an integral functional unit which may play an organizational tole in the formation of cartilagenous matrix during development. Furthermore, it may contribute to the mechanical strength of the coflagen framework in hyaline cartilage.     

Fine structure and cytochemistry of the nuclei of the primitive ciliateTracheloraphis crassus (Karyorelictida)

Summary The nuclei ofTracheloraphis crassus were studied using light and electron microscopy combined with Bernhard's RNP staining and pronase digestion. The nuclear apparatus of this species consists of a longitudinal row of 11–43 macronuclei and 4–16 micronuclei. Like in all karyorelictids, the macronuclei are unable to divide and become segregated during cytokinesis; their number is supplemented in every cell cycle by differentiation of several new macronuclei from micronuclei.Each adult macronucleus contains a single compact endonuclear aggregate of several large chromocenters, readily destained with EDTA, and several RNP containing nucleoli. There is continuity between the material of the chromocenters and the decondensed DNP fibrils in the nuclear matrix. The nucleoli contain NORs in the form of fibrillar centers. The endonuclear aggregate includes also groups of RNP granules which are especially resistant to EDTA destaining. A microfibrillar sphere, usually localized at the periphery of the aggregate, contacts one or several nucleoli. The sphere is not bleached with EDTA, and only its periphery becomes digested with pronase. The macronuclear matrix consists of both protein fibrils and pronase-resistant fibrils, the latter being localized at the nuclear periphery.Developing macronuclear primordia contain loose strands of decondensed chromatin; only later they form chromocenters and nucleoli.The micronuclei reproduce by mitosis with typical chromosomes (2n=66). During interphase, they are filled with condensed chromatin which can be bleached with EDTA; they form no nucleoli. Ring-like lamellae, existing in the cavities of the chromatin mass, stain for RNA (after Bernhard) and are pronase-sensitive. These lamellae resemble the kinetochore material conserved during interphase in another karyorelictid ciliate,Trachelocerca geopetiti.     

Localization of microtubules during macronuclear division in Tetrahymena and possible involvement of macronuclear microtubules in 'amitotic' chromatin distribution

The ciliated protozoa Tetrahymena contains two nuclei, a micronucleus and a macronucleus. In the vegetatively growing cell, the macronucleus divides amitotic while the micronucleus divides by mitosis. It has been indicated that microtubules are involved in macronuclear division and microtubules are observed to exist in the dividing macronucleus. To clarify the localization and the organization of microtubules in the amitotic dividing macronuclei, we used immunofluorescent staining technique. The microtubules were observed in the cytoplasm and macronucleus. The microtubules were organized and dynamically changed their distribution throughout the macronuclear division. We suggest a possibility that these microtubules are involved in 'amitotic' distribution of chromatin throughout the macronuclear division.     

RNA TRANSPORT FROM NUCLEUS TO CYTOPLASM IN CHIRONOMUS SALIVARY GLANDS

The fine structure and cytochemistry of the extremely large RNA puffs, or Balbiani rings, in salivary gland nuclei of midge, Chironomus thummi, larvae have been investigated. The Balbiani rings are composed of a diffuse mass of electron-opaque 400 to 500 A granules, short threads about 180 to 220 A in diameter and associated fine chromatin fibrils. These components appear to be organized into brushlike elements which form the ring. Electron microscope cytochemistry has shown that the granules and short threads contain RNA. After ribonuclease digestion, only 50 to 100 A chromatin fibrils were apparent in the Balbiani ring, and the granules were no longer demonstrable. Deoxyribonuclease digestion had no apparent effect on these structures. Observations indicate that the granules are formed from the short threads and released into the nucleoplasm in which they are evenly distributed. At the nuclear envelope, many granules have been observed partially or completely within the nuclear pores. These granules become elongated and are shown to penetrate the center of the pore in a rodlike form, about 200 A in diameter. The Balbiani ring granules are not normally visible within the cytoplasm adjacent to the nuclear envelope, but have been rarely found in this region. It is suggested that the granules represent the product of the Balbiani ring, possibly a messenger RNA bound to protein, and that they regularly pass into the cytoplasm through a narrow central channel in the pores of the nuclear envelope.     

Electron Microscopy of the Hypotrich Ciliate Oxytricha platystoma, with Consideration of its Macronuclear Organization

SYNOPSIS. The body of Oxytricha platystoma is covered with 2 membranes, the outer or pellicular membrane and the inner or cytoplasmic membrane. Each cirrus consists of a bundle of 25-50 cilia. There are 2 macronuclei and 2 micronuclei. The micronucleus is a very small body containing dense Feulgen-positive material. The macronucleus is an elongated body surrounded by a double membrane. The dense Feulgen-positive material is embedded in a less dense nucleoplasm. Some larger bodies found inside the nucleus may be nucleoli. There is a single reorganization band in each macronucleus. It consists of a solution plane and a reconstruction plane, and has a total thickness of 1.5 μ. The macronucleus divides amitotically, whereas the micronucleus divides mitotically.     

Ultrastructure of the nuclear apparatus of the lower ciliateRemanella granulosa Kahl (Karyorelictida)

Summary The nuclear apparatus ofRemanella granulosa has been investigated using conventional TEM methods and Bernhard's technique of preferential RNP staining. This species has two (rarely three) macronuclei and a single micronucleus (rarely two micronuclei). The nuclei always form a single group.The macronuclei contain a fibro-granular matrix resistant to EDTA destaining, and several nucleoli and chromatin bodies. The chromatin bodies are readily bleached with EDTA and are often clustered, or even fused, forming chromocenters. The nuclei are of the compact concentric type. Some macronuclei contain nuclear bodies, as finely fibrous spheres or bundles of coarse fibers, or both. Neither type of nuclear body is destained with EDTA. The spheres are frequently associated with nucleoli. There is no evidence of any transition between the two types of nuclear bodies. The macronuclear envelope contains numerous pore complexes and is strengthened with an electron dense layer. The micronucleus is filled with spongy condensed chromatin and surrounded by an envelope with occasional pores. This nucleus lacks nucleoli and nuclear bodies.     

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.     

Interactions between newly developed macronuclei and maternal macronuclei in sexually immature multinucleate exconjugants of Paramecium caudatum

The macronucleus of Paramecium caudatum controls most cellular activities, including sexual immaturity after conjugation. Exconjugant cells have two macronuclear forms: (1) fragments of the maternal macronucleus, and (2) the new macronuclei that develop from the division products of a fertilization micronucleus. The fragments are distributed into daughter cells without nuclear division and persist for at least eight cell cycles after conjugation. Conjugation between heterokaryons revealed that the fragmented maternal macronuclei continued to express genetic information for up to eight cell cycles. When the newly developed macronucleus was removed artificially within four cell cycles after conjugation, the clones regenerated the macronuclear fragments (macronuclear regeneration; MR) and showed mating reactivity, because they were sexually mature. However, when the new macronucleus was removed during later stages, many MR clones did not show mating reactivity. In some extreme cases, immaturity continued for more than 50 fissions after conjugation, as seen with normal clones that had new macronuclei derived from a fertilization micronucleus. These results indicate that the immaturity determined by the new macronucleus is not annulled by the regenerated maternal macronucleus. Mature macronuclear fragments may be "reprogrammed" in the presence of the new macronucleus, resulting in their expression of "immaturity."     

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.     

Light and Electron Microscopy of the Spore of Myxobolus heckelii n. sp. (Myxozoa), Parasite from the Brazilian Fish Centromochlus heckelii (Teleostei, Auchenipteridae)

ABSTRACT. A myxosporean parasitizing the gill filaments of the freshwater teleost fish Centromochlus heckelii collected in the Tocantins River (Lower Amazonian Region, Brazil) is described using light and electron microscopy. This parasite produces spherical to ellipsoidal cyst-like plasmodia up to 250 μm in diameter, with a thick wall strengthened by several stratified juxtaposed crossed collagen layers, whose thickness varies according to the number of the layers. Several compressed fibroblasts are observed among the collagen fibrils. Deposits of spherical dense material are scattered at the internal periphery of the cysts. Plasmodia and different developmental stages, including immature and mature spores, filled the central region of the cysts. The spore body is ellipsoidal in valvar view and biconvex in sutural view. It is formed by two equal-sized and symmetric valves measuring 12.7 μm long (12.2–13.1) ( n =50), 6.6 μm wide (6.3–6.9) ( n =25), and 4.0 μm (3.7–4.4) ( n =20) thick. A thin layer formed by fine and anastomosed microfibrils is observed at the spore surface. Two equal, elongated pyriform polar capsules measure 2.9 μm (2.7–3.3) × 1.7 μm (1.4–2.0) ( n =25), each containing four or five oblique polar filament coils. The binucleated sporoplasm contains numerous spherical sporoplasmosomes, glycogen particles, and a large vacuole with fine granular matrix. Based on the morphological and ultrastructural differences and specificity of the host, we describe this isolate as a new myxosporidian, Myxobolus heckelii n. sp. (Myxozoa, Myxosporea).     

Structural aspects of amitosis: a light and electron microscope study of the isolated macronuclei of Paramecium aurelia and Tetrahymena pyriformis

Thin sections show the macronuclei of Paramecium aurelia and Tetrahymena pyriformis to contain two types of bodies. The smaller, measuring 0.1–0.2 in diameter, have been resolved in the light microscope by first removing the macronuclei from the cells in the presence of Mg⁺⁺, then chelating that divalent cation with EDTA, resulting in expansion of the nuclear material. By staining with methyl green, Azure B, and the Feulgen procedure, the small bodies were shown to contain DNA. In whole mounts these small bodies appear to be joined to one another producing a complex network suspended in which are the larger bodies, or nucleoli. — Macronuclei from both ciliates were isolated in large quantities and purified for spreading on an air-water interface. When the nuclei burst from surface tension forces and are examined with the electron microscope, the DNA containing bodies remain attached to one another by means of 100 Å fibrils. The pattern of attachment is non-linear. Occasionally individual DNA-containing bodies loosen revealing a coil resembling both in shape and dimensions the 250 Å coil characteristic of eucaryotic chromatin. The substructure of the 250 Å coil has not been directly observed. However, the frequent association of pairs of 100 Å fibrils makes it likely that two such fibrils are tightly complexed in the 250 Å coil. The 100 Å fibril, in turn, contains two 20 Å strands, each presumably a DNA double helix. — In Paramecium each small body of the macronucleus contains approximately one chromosome-equivalent of DNA. The fact that these small bodies are joined to form large structured masses of chromatin within the macronucleus indicates that the distribution of genetic material is not random. It is possible that, similar to bacteria, entire genomes segregate as units, thus accounting for successful amitotic division.This work was supported by a Predoctoral Fellowship to the author from the National Institutes of Health, U.S. Public Health Service, and by grant GM-13882 (NIH-USPHS) to Dr. Daniel Mazia.     

The intranuclear helices of Euplotes: Their substructure,localization, and apparent migration to the cytoplasm

Study of the fine structure of the macronucleus in Euplotes eurystomus, a ciliate protozoon, during various stages of the cell division cycle has yielded new information about intranuclear helices. They are frequently observed at the periphery of chromatin bodies or next to the nuclear envelope, and they appear to be a constituent of nucleoli. The fibril that forms a helix is about 11–15 nm thick, and torus profiles of helices cut in cross section are about 35 nm in diameter. In substructure the helix is composed of a thin strand 3–5 nm thick which is coiled to form the 11–15 nm fibril; so the helix is a super-coiled structure. The intranuclear helices are present in the macronucleus throughout the cell cycle. They do not show obvious changes of relative abundance nor changes of relative localization in the nucleus, with one exception: they were never observed in the diffuse zone of replication bands. Evidence is presented indicating that nuclear helices migrate to the cytoplasm through nuclear pores. Although the chemical composition of the Euplotes intranuclear helices is unknown, information in the literature on similar helices in Amoeba indicates that they contain RNA and not DNA. The observations on Euplotes helices are consistent with a concept of “packaged” RNA for transport to the cytoplasm.     

Isolation of an extracellular Mn-dependent enzyme mineralizing melanoidins from the white rot fungus Trametes versicolor

Abstract Morphological and physiological properties of Tetrahymena thermophila immobilized by encapsulation in calcium-alginate hollow spheres were found to be substantially different from those of suspended cells. Immobilized T. thermophila reached lengths of 70–100 μm, whereas the average cell of suspension cultures was about 40 μm long. Suspended cells appeared typically pear-shaped while immobilized cells developed a proboscis-like anterior end. Contrary to suspended T. thermophila , encapsulated cells were functionally deficient in phagocytosis although developing an oral apparatus. The diameter of the macronucleus of immobilized cells was about two times larger than the macronucleus of suspended cells and contained twice as much DNA, while the DNA content of the micronucleus remained unchanged. High cell density fermentations of suspended cells indicated that the alterations observed in immobilized cells were not due to close physical contacts between the cells.