Cell differentiation during early development of Nassarius reticulatus L. (Gastropoda,prosobranchia)

Summary In Nassarius reticulatus the nuclei and nucleoli undergo important morphological changes from the zygote to the 16-cell stage. In the zygote and in the trefoil (2-cell) and 4-cell stage, several agranular, fibrillar nucleolus-like bodies 1 m diameter are present in the interphase nucleus. Granular nucleoli first appear at the 8-cell stage. These nucleoli have fibrillar and granular regions. The granular regions are made up predominantly of ribosome-like osmiophilic granules. From the 16 and 32-cell stage onwards, the one or two spherical nucleoli of each nucleus measure 2.5 m in diameter and show a concentric organization with a very dense central region surrounded by a broad peripheral zone containing numerous granules, possibly of ribonucleoprotein. At the same time the number of ribosome-like particles increase in the karyoplasm and that of ribosomes in the cytoplasm. These findings are surprising because in eggs with radial cleavage, which have been subjected to more detailed analysis, the first granular nucleoli appear after the end of the cleavage, at the blastula or gastrula stage. The early appearance of granular nucleoli which seem to be characteristic of several eggs with spiral cleavage is discussed in connection with biochemical data on RNA-synthesis.This investigation was supported by the Deutsche Forschungsgemeinschaft and the Stiftung VolkswagenwerkWe wish to thank Mrs. C. Mehlis for valuable technical assistance and Prof. J. Bergerard for the excellent working conditions at the Station biologique at Roscoff (France)     

RNA-protein interactions of stored 5S RNA with TFIIIA and ribosomal protein L5 during Xenopus oogenesis

We studied the pathway of 5S RNA during oogenesis in Xenopus laevis from its storage in the cytoplasm to accumulation in the nucleus, the sequence requirements for the 5S RNA to follow that pathway, and the 5S RNA-protein interactions that occur during the mobilization of stored 5S RNA for assembly into ribosomes. In situ hybridization to sections of oocytes indicates that 5S RNA first becomes associated with the amplified nucleoli during vitellogenesis when the nucleoli are activity synthesizing ribosomal RNA and assembling ribosomes. When labeled 5S RNA is microinjected into the cytoplasm of stage V oocytes, it migrates into the nucleus, whether microinjected naked or complexed with the protein TFIIIA as a 7S RNP storage particle. During vitellogenesis, a nonribosome bound pool of 5S RNA complexed with ribosomal protein L5 (5S RNPs) is formed, which is present throughout the remainder of oogenesis. Immunoprecipitation assays on homogenates of microinjected oocytes showed that labeled 5S RNA can become complexed either with L5 or with TFIIIA. Nucleotides 11 through 108 of the 5S RNA molecule provide the necessary sequence and conformational information required for the formation of immunologically detectable complexes with TFIIIA or L5 and for nuclear accumulation. Furthermore, labeled 5S RNA from microinjected 7S RNPs can subsequently become associated with L5. Such labeled 5S RNA is found in both 5S RNPs and 7S RNPs in the cytoplasm, but only in 5S RNPs in the nucleus of microinjected oocytes. These data suggest that during oogenesis a major pathway for incorporation of 5S RNA into nascent ribosomes involves the migration of 5S RNA from the nucleus to the cytoplasm for storage in an RNP complex with TFIIIA, exchange of that protein association for binding with ribosomal protein L5, and a return to the nucleus for incorporation into ribosomes as they are being assembled in the amplified nucleoli.     

Immunoelectron microscopic study of polyamines in the gastrointestinal tract of rat

Polyamines (PAs) are ubiquitous polycationic metabolites in the eukaryotic and prokaryotic cells and are believed to be intimately involved in the regulation of DNA, RNA, and protein biosynthesis. However, the subcellular localization of PAs has not yet been fully elucidated in a variety of cell types. In the present study, a pre-embedding indirect immunoperoxidase approach was used to define the fine structural localization of PAs in the gastrointestinal tract of rat, which was fixed with glutaraldehyde and the monoclonal antibody ASPM-29 specific for spermine (Spm) and spermidine (Spd). Examination by a transmission electron microscopy showed that the peroxidase end products were commonly and predominantly localized in the free and attached ribosomes of the rough endoplasmic reticulum (rER) in the active protein- or peptide-secreting cells, and in rapidly proliferating cells including the gastric chief cells, mucous neck cells, and intestinal crypt cells. The nuclei, mitochondria, and secretory vesicles were devoid of PAs. Of note is the new finding that PAs are also located even on the small number of ribosomes in the cytoplasm of the parietal cells and of the villus-tip cells, because these were the cell types that were found to be almost PA-negative at the light microscopic level. These results seem to be completely consistent with those recently obtained for rat neurons. Thus, the present study generalized the subcellular localization of PAs on the ribosomes, and demonstrated that PAs are one of the components of biologically active ribosomes, possibly in any type of cell, that are closely involved in the translation processes of protein biosynthesis.     

Sertoli cell development of pig testis in the fetal and neonatal period

The Sertoli cells of pig fetuses from 35 days postcoitum until 1 mo after birth have been investigated by light and electron microscopy in decapitated animals and their control littermates, as well as in untreated animals. Until 52 days postcoitum, Sertoli cells change in form during the formation of sex cords but from then onwards they are rather uniform. They primarily display an elongated nonindented nucleus with one or more prominent nucleoli, a well-developed Golgi apparatus, and in the basal compartment below or beside the nucleus, a large lipid droplet. There are large quantities of rough endoplasmic reticulum (RER) from 52 days postcoitum onwards, often with complex whirl forms and a parallel arrangement of profiles with relatively few ribosomes. After birth their numbers seem to be somewhat less, and by 1 mo after birth the RER profiles are often shorter and almost free of ribosomes. Clustered ribosomes are found in large quantities throughout the period under investigation. Especially in the early fetal period, the endoplasmic reticulum (ER) profiles show prominently filled cisternae. Mitochondria are mostly long and slender, or small and ovoid. Most have lamellar cristae, but mixed lamellar-tubular cristae can also be seen. Between decapitated, control and untreated animals no obvious ultrastructural differences could be observed. The peritubular cell sheath surrounding the sex cords did not show signs of differentiation into a layer of myoid cells.     

The murine gene, Traube, is essential for the growth of preimplantation embryos

Little is known about the genetic control of preimplantation development. We have isolated, characterized, and mutated a previously undescribed mouse gene, Traube (Trb), essential for preimplantation development. Similar protein coding sequences are found in rats, humans, and yeast. The TRB protein contained two amino-terminal acidic domains, a leucine zipper, and three putative nuclear localization signals. The Trb gene was expressed at low levels ubiquitously early in development and became restricted to the liver and the central nervous system from E11.5 onward. Myc-tagged TRB protein was localized to the nucleus, and in a large proportion of the cells to the nucleoli. The Trb mutant embryos halted in development at the compacted morula stage at E2.5. At E3.5 they started to decompact and a day later they disintegrated and died. The observed defect was cell autonomous, as mutant cells failed to participate in the formation of chimeric embryos. The Trb mutant embryos showed a 50% reduction of the total cell number. The mutant embryos exhibited a paucity of ribosomes, polyribosomes, and rough endoplasmic reticulum. This paucity of ribosomes together with the localization of TRB to the nucleoli, the site of ribosome synthesis, suggests that TRB is involved in the synthesis of ribosomes.     

FINE STRUCTURE OF THE ZYGOTE AND EARLY EMBRYO IN QUERCUS GAMBELII

This investigation begins with the late zygote and traces ultrastructural development to the late globular stage of the embryo. Two nucleoli and satellite nucleoli sometimes occur in the zygote nucleus. Mitochondria, dictyosomes, cytoplasmic ribosomes, rough ER, and lipid bodies are numerous in the zygote. Microbodies are occasionally seen. The cell wall becomes well developed before the first division. No plasmodesmata occur in the zygote wall. The basal cell of the proembryo and the suspensor cells of the later embryo have very dense cytoplasm with a high concentration of cytoplasmic ribosomes. The nuclei are very electron opaque. The terminal cell and the cells of the embryo proper have a fine structure similar to that of the zygote. Plastids increase in number, size, starch content, and amount of thylakoid lamellae as the embryo develops. Mitochondria are numerous and appear active at all stages. Dictyosome activity, ribosomal aggregation, and the amount of ER are highest during the late globular stage. Lipid bodies are present up to the early globular stage, then disappear. The inner cell walls of the embryo are thin and have many plasmodesmata. These walls begin to thicken at the late globular stage, and at this time the size of the embryo begins to show an increase over that of the zygote. The results show a corresponding increase in the amount and activity of the metabolic machinery as the development of the embryo progresses. Lipids are probably more important as a nutrient source in the zygote and early embryo; starch becomes more important in the late stages. Absorption of nutrient material into the embryo sac and developing embryo appears to be from the chalazal end.     

ELECTRON MICROSCOPIC AUTORADIOGRAPHY OF GERMINAL CENTER CELLS IN MOUSE SPLEEN

The fine structure of tritiated thymidine-labeled cells in antigen-stimulated mouse spleen germinal centers is described. In studies on the ultrastructural level, two labeled cell types found in germinal centers are observed. Large lymphocytes are characterized by their very numerous free ribosomes, a paucity of endoplasmic reticulum, relatively few mitochondria, and a poorly developed Golgi region. The nuclei are large and vesicular, and large nucleoli are present. A second labeled cell type appears to contain more mitochondria and has a higher development of the Golgi area. The nucleus contains large, numerous blocks of chromatin, indicative of a more differentiated cell type. Reticular cells, both phagocytic and non-phagocytic, were not observed to be labeled in the germinal centers.     

Morphological study of the mammalian stress response: characterization of changes in cytoplasmic organelles, cytoskeleton, and nucleoli, and appearance of intranuclear actin filaments in rat fibroblasts after heat-shock treatment

Using both electron microscopy and immunological methods, we have characterized a number of changes occurring in rat fibroblasts after heat-shock treatment. Incubation of the cells for 3 h at 42 degrees-43 degrees C resulted in a number of changes within the cytoplasm including: a disruption and fragmentation of the Golgi complex; a modest swelling of the mitochondria and subtle alterations in the packing of the cristae; and alterations in cytoskeletal elements, specifically a collapse and aggregation of the vimentin-containing intermediate filaments around the nucleus. A number of striking changes were also found within the nuclei of the heat-treated cells: (a) We observed the appearance of rod-shaped bodies consisting of densely packed filaments. Using biochemical and immunological methods, these nuclear inclusion bodies were shown to be comprised of actin filaments. (b) Considerable alterations in the integrity of the nucleoli were observed after the heat-shock treatment. Specifically, there appeared to be a general relaxation in the condensation state of the nucleoli, changes in both the number and size of the granular ribonucleoprotein components, and finally a reorganization of the nucleolar fibrillar reticulum. These morphological changes in the integrity of the nucleoli are of significant interest since previous work as well as studies presented here show that two of the mammalian stress proteins, the major stress-induced 72-kD protein and the 110-kD protein, localize within the nucleoli of the cells after heat-shock treatment. We discuss these morphological changes with regards to the known biological and biochemical events that occur in cells after induction of the stress response.     

Cellular and biochemical events in mammalian cells during and after recovery from physiological stress

We have examined and compared a number of cellular and biochemical events associated with the recovery process of rat fibroblasts placed under stress by different agents. Metabolic pulse-labeling studies of cells recovering from either heat-shock treatment, exposure to sodium arsenite, or exposure to an amino acid analogue of proline, L-azetidine 2-carboxylic acid, revealed interesting differences with respect to the individual stress proteins produced, their kinetics of induction, as well as the decay in their synthesis during the recovery period. In the initial periods of recovery, the major stress-induced 72-kD protein accumulates within the altered nucleoli in close association with the pre-ribosomal-containing granular region. During the later times of recovery from stress, the nucleoli begin to regain a normal morphology, show a corresponding loss of the 72-kD protein, and the majority of the protein now begins to accumulate within the cytoplasm in three distinct locales: the perinuclear region, along the perimeter of the cells, and finally in association with large phase-dense structures. These latter structures appear to consist of large aggregates of phase-dense material with no obvious encapsulating membrane. More interestingly we show, using double-label indirect immunofluorescence analysis, that much of the perinuclear and cell perimeter-distributed 72-kD protein coincides with the distribution of the cytoplasmic ribosomes. We discuss the possible implications of the presence of the 72-kD stress proteins within the pre-ribosomal-containing granular region of the nucleolus as well as its subsequent colocalization with cytoplasmic ribosomes in terms of the translational changes which occur in cells both during and after recovery from physiological stress.     

Pescadillo is essential for nucleolar assembly,ribosome biogenesis,and mammalian cell proliferation

Mutation of the zebrafish pescadillo gene blocks expansion of a number of tissues in the developing embryo, suggesting roles for its gene product in controlling cell proliferation. We report that levels of the pescadillo protein increase in rodent hepatocytes as they enter the cell cycle. Pescadillo protein localizes to distinct substructures of the interphase nucleus including nucleoli, the site of ribosome biogenesis. During mitosis pescadillo closely associates with the periphery of metaphase chromosomes and by late anaphase is associated with nucleolus-derived foci and prenucleolar bodies. Blastomeres in mouse embryos lacking pescadillo arrest at morula stages of development, the nucleoli fail to differentiate and accumulation of ribosomes is inhibited. We propose that in mammalian cells pescadillo is essential for ribosome biogenesis and nucleologenesis and that disruption to its function results in cell cycle arrest.     

Relations between nucleolar morphometric parameters and pre-rRNA synthesis in animal and plant cells

In order to study if there are differences between cells of the same tissue with one and two nucleoli, nuclear and nucleolar volume, density of tritiated uridine incorporation, amount of DNA per nucleus and intensity of cytoplasmic basophilia were measured in mononucleolated and binucleolated rat epithelial endometrial cells, in onion root meristematic cells and in chick embryo matrix cells of the central nervous system, neuroblasts and neurons. No significant differences in nuclear volume, density of tritiated uridine incorporation and amount of DNA per nucleus were found between cells of the same type with diverse numbers of nucleoli. Binucleolated endometrial cells, matrix cells, and root meristematic cells have biphasic distributions of nucleolar volumes. One peak of this distribution roughly coincides with the nucleolar volume of mononucleolated cells, the other peak corresponds almost to double the volume. As the density of uridine incorporation is the same irrespective of the nucleolar number and volume, the cells with larger nucleolar volumes have higher pre-rRNA synthesis. These cells also have higher amounts of ribosomes in the cytoplasm, as revealed by the photometric study of basophilia. It is concluded that in this population of cells the ribosomal production is regulated to a higher steady equilibrium than in the general population. This difference is not due to polyploidism or to the increased DNA content of G2 phase cells. Binucleolated neuroblasts and neurons have nucleolar volumes similar to those of mononucleolated ones.     

Polyamines in spermatocytes and residual bodies of rat testis

Immunocytochemistry for polyamines in the rat testis revealed intense staining of small bodies close to the lumen of seminiferous tubules of spermatogenic stage VII and VIII as well as of spermatocytes. Methyl green-pyronin and propidium iodide staining combined with DNase or RNase predigestion showed that the small bodies contained RNA, but not DNA and double fluorescence staining showed that polyamines (PAs) colocalized with RNA in the bodies. Electron microscopy confirmed the absence of nuclei in the bodies and revealed that PA immunoreactivity was associated with ribosomes. These results strongly suggest that the small bodies correspond to the residual bodies, and agree with previous results showing localization of PAs to ribosomes in neurons and gastrointestinal epithelial cells. The accumulation of PAs in residual bodies may reflect a termination of their role in spermiogenesis with respect to protein synthesis.     

Autoradiographic, ultrastructural and interferometric analyses of the temperature effect on the synthesis and migration of ribosomes in root meristem cells of Helianthus annuus L. relation to S phase initiation

Experimental model consisted in blocking cells in G1 phase by cold treatment (12 h, 10 degrees C); following 3 h of postincubation at 20 degrees C, cells initiated S phase. In the present studies it has been shown that 2 h postincubation at 20 degrees C of cold-treated young seedlings of Helianthus annuus L. results in transformation of inactive meristematic nucleoli, characterized by small sizes, reduced amount of dry mass and granular component and by the presence of few and large fibrillar centres into large active nucleoli displaying high dry mass and granular component contents, numerous and small fibrillar centres. After 3 h of postincubation at 20 degrees C, nucleoli lose their granular component, decrease in size and dry mass content. At this moment cytoplasm enriches in ribosomes and its dry mass increases. Maximum of nucleolar activity is preceded by an accumulation of proteins in nucleoli. It is concluded that an enhanced transport of ribosomes is one of the conditions of S phase initiation.     

A cytological study of the ovary of Rhodnius prolixus. III. Cytoarchitecture and development of the trophic chamber

The tropharium of the telotrophic ovarioles of Rhodnius is syncytial with the nurse cell nuclei located in tortuous finger-like projections arborizing from a common cytoplasmic area, the trophic core. The nurse cell nuclei exhibit prominent nucleoli. Located adjacent to the nuclear envelope are masses of granular material both within the nucleus and adjoining cytoplasm. The cytoplasm consists primarily of ribosomes and mitochondria. The trophic core and the trophic cords that connect the core to individual oocytes characteristically possess parallel arrays of microtubules with ribosomes and mitochondria interspersed between. Surrounding the nurse tissue (germarium) is a thin layer of squamous cells comprising the inner sheath. The inner sheath is encompassed by the non-cellular tunica propria superficial to which are two external cellular sheaths. The syncytial nature of the tropharium appears to arise as a result of the fusion of many entangled nurse cell-oocyte complexes during the late fifth instar. The structural similarities, and possible homologies with the polytrophic type of ovariole is discussed.     

An ultrastructural and histochemical study of oogenesis in the trichostrongylid nematode Heligmosomoides polygyrus

Oogenesis in trichostrongylids has been examined for the first time in a light and electron microscopic investigation of Heligmosomoides polygyrus. The female reproductive tract is a single straight tube containing small oogonia (6 micron in diameter), which are arranged in a rosette pattern around a central rachis at the anterior end of the tract. Developing oocytes separate from the rachis and pass posteriorly in single file down the growth zone. Oocytes increase rapidly in volume due to the accumulation of cytoplasmic inclusion granules. These granules are of 3 types. Type 1 granules are amorphous and probably consist primarily of lipoprotein. Type 2 granules are large lipid inclusions and type 3 granules are electron-dense lipoprotein yolk bodies, which are probably used for energy reserves in the developing embryo. Histochemical studies show a more intense reaction for DNA in the nuclei of oogonia than in the nuclei of oocytes. There is a strong reaction for RNA in the nucleoli and in the cytoplasm of oogonia and oocytes. Ultrastructural studies indicate that this RNA is probably in the form of rRNA in the abundant ribosomes. Mature oocytes are cylindrical (60 X 70 micron), have a distinct nucleus with nuclear pores, and the cytoplasm is filled with inclusion granules and ribosomes but contains only small amounts of glycogen. Prior to fertilization the plasma membrane of oocytes acquires a flocculent coat. These oocytes contain 6 distinct bivalent chromosomes in diakinesis. Thus the major changes that occur in developing germ cells are 2-fold: nuclear changes that prepare the chromosomes for fertilization by initiating reduction division, and cytoplasmic changes that involve the synthesis and storage of inclusion granules.     

Non-ribosomal nucleolar proteins in HeLa cells

The study of nucleolar macromolecular components has previously emphasized ribosomal precursor and mature RNA, or ribosomal structural proteins. In this work, we have stressed the purification of nucleoli, and have studied their protein composition. The results indicate that there exists in highly purified nucleoli of HeLa cells, a class of high molecular weight polypeptides which have been identified by means of size, kinetics of turnover, and metabolic behavior to be non-ribosomal nucleolar-specific proteins. The possibility that these proteins play a part in the assembly of mature ribosomes is discussed.     

DNA and nuclear aggregates of polyamines

Polyamines (PAs) are linear polycations that are involved in many biological functions. Putrescine, spermidine and spermine are highly represented in the nucleus of eukaryotic cells and have been the subject of decades of extensive research. Nevertheless, their capability to modulate the structure and functions of DNA has not been fully elucidated. We found that polyamines self-assemble with phosphate ions in the cell nucleus and generate three forms of compounds referred to as Nuclear Aggregates of Polyamines (NAPs), which interact with genomic DNA. In an in vitro setting that mimics the nuclear environment, the assembly of PAs occurs within well-defined ratios, independent of the presence of the DNA template. Strict structural and functional analogies exist between the in vitro NAPs (ivNAPs) and their cellular homologues. Atomic force microscopy showed that ivNAPs, as theoretically predicted, have a cyclic structure, and in the presence of DNA, they form a tube-like arrangement around the double helix. Features of the interaction between ivNAPs and genomic DNA provide evidence for the decisive role of "natural" NAPs in regulating important aspects of DNA physiology, such as conformation, protection and packaging, thus suggesting a new vision of the functions that PAs accomplish in the cell nucleus.     

A comparative histochemical study of fish (Channa maruleus) and amphibian (Bufo stomaticus) oogenesis

Summary Comparative histochemical studies on the fish (Channa maruleus) and amphibian (Bufo stomaticus) oogenesis demonstrate a great similarity in the growth and differentiation of their egg follicle. The ooplasm, germinal vesicle and egg-membranes show distinct morphological and cytochemical changes during previtellogenesis and vitellogenesis.During previtellogenesis the various components of the follicle are engaged in the synthesis of protoplasm as shown by the proliferation of yolk nucleus substance, mitochondria and some lipid bodies in the ooplasm and of nucleoli in the germinal vesicle. The substance of the yolk nucleus consisting of proteins, lipoproteins and RNA first appears adjacent to the nuclear membrane. Numerous mitochondria of lipoprotein composition, and some lipid bodies consisting of unsaturated phospholipids lie in association with the yolk nucleus which forms substratum for the former. The lipid bodies, present inside the germinal vesicle, follicular epithelium, and adjacent to the plasma membrane in association with some pinocytotic vacuoles, have been considered to play a significant role in the active transport of some substances from the environment into the ooplasm and from the latter into the germinal vesicle. The follicular epithelium itself is very poorly developed, negating its appreciable role in the contribution of specific substances into the oocyte, which seem to be contributed by the germinal vesicle showing a considerable development of nuclear sap, basophilic granules and nucleoli consisting of RNA and proteins; many large nucleoli bodily pass into the cytoplasm during the previtellogenesis of Channa, where their substance is gradually dissolved. The intense, diffuse, basophilic substance of the cytoplasm is believed due to free ribosomes described in many previous ultrastructural studies.During vitellogenesis, the various deutoplasmic inclusions, namely carbohydrate yolk, proteid yolk and fatty yolk, are deposited in the ooplasm. The carbohydrate yolk bodies rich in carbohydrates originate in association with the plasma membrane and correspond to vesicles and cortical granules of previous studies. The proteid yolk consisting of proteins and some lipoproteins, and fatty yolk containing first phospholipids and some triglycerides and then triglycerides only are deposited under the influence of yolk nucleus substance, mitochondria and cytoplasm. The mitochondria and yolk nucleus substance foreshadow in some way the pattern of these two deutoplasmic inclusions and persist at the animal pole of mature egg while the other inclusions of previtellogenesis disappear from view. The pigment granules, which also show a gradient from the animal to vegetal pole in Bufo, are also formed in association with yolk nucleus substance and mitochondria. Some glycogen also appears in both the species. The nuclear membrane becomes irregular due to the formation of lobes. The lipid bodies of the germinal vesicle come to lie outside the nuclear membrane, suggesting active transport of some substances into the ooplasm; many nucleoli bodily pass into the ooplasm of Bufo, where they are gradually absorbed. The amount of basophilic granules is considerably increased in the germinal vesicle during vitellogenesis. Various egg-membranes such as outer epithelium, thin theca, single-layered follicular epithelium, zona pellucida or vitelline membrane surround the vitellogenic oocytes. The zona pellucida formed between the oocyte and follicle cells consists of a carbohydrate-protein complex. The follicle cells show lipid droplets, mitochondria and basophilic substance in their cytoplasm. The various changes that occur in the components of the follicle during vitellogenesis seem to be initiated by gonadrotrophins formed under the influence of specific environmental conditions.The author wishes to express sincere appreciation and gratitude to Dr. Gilbert S. Greenwald, who has made the completion of this investigation possible.Ph. D. Population Council Post-doctoral Fellow.