Ultrastructural and cytochemical features of the supramedullary neurons of the pufferfish Diodon holacanthus (L.) (Osteichthyes)

Exceptionally high DNA contents were found in supramedullary neuron (SN) nuclei of the pufferfish Diodon holacanthus by quantitative microfluorimetric assay. This phenomenon has been explained by endoreplication, the functional significance of which is still unclear. In this view, the peptidergic nature and large dimensions make the teleostean clustered SN an interesting model for investigating the relationships between endoreplication, nuclear morphology and biosynthetic cellular activity. In this paper, we present a cytochemical and ultrastructural study on the SN of D. holacanthus (Tetraodontiformes). The nucleolar and nucleus structures suggest an intense production of ribosomal components in order to satisfy high cellular demands for protein synthesis. Accordingly, the cytoplasmic compartment presents an extensive rough endoplasmic reticulum, well-developed Golgi apparatus and a remarkable vesicular traffic. These features suggest that SN are engaged in an intense process of protein biosynthesis. The SN are completely surrounded by processes of different types of glial cells. The glial cells may be considered part of the SN cluster.     

Morphological, cytochemical, and cytofluorimetric features of supramedullary neurons of the fish Solea ocellata

Various teleost species belonging to different orders possess a particular neuronal system formed by giant supramedullary neurons (SNs). In some species, SNs are scattered along the spinal cord; in others they are organized in a compacted and well-defined cluster located at the boundary between the medulla oblongata and spinal cord. In addition to the many morphological, physiological, and histochemical studies performed both in vivo and in vitro by several authors since the end of the 19th century, quantitative microfluorometric evaluation of the DNA content of SNs has showed that clustered SNs but not aligned SNs have a DNA content much greater than the normal value of 2C. Such a high DNA content is exceptional for vertebrate neurons. In the present study, we extend this analysis of SNs to the fish Solea ocellata. Our results show that the organization of the SNs of S. ocellata is neither strictly aligned nor clustered, but somewhere in between, and that this is also true of both their morphological characteristics and DNA content values. Interspecific differences in the distribution and morphology of SNs may reflect functional differences, possibly related to environmental or behavioral differences among species. In addition, the possible functional significance of endoreplication in SNs is discussed.     

Glial cells: basic components of clusters of supramedullary neurons in pufferfish

In this paper a cytochemical and ultrastructural study of clustered supramedullary neurons (SN) of Tetraodon fluviatilis (Tetraodontiformes) is presented. SN are large-sized nerve cells that have a high metabolic rate and are intensely engaged in protein biosynthesis. The SN are completely surrounded by two types of glial cell, which have been ultrastructurally, histochemically and immunohistochemically identified as astrocyte-like cells and microglial cells. The glial cells are located very close to the SN and sometimes contact them, which suggests that they do not only provide mechanical support but are also trophic for the SN and serve their functioning. We consider these glial cells as a constitutive and functional part of the cluster of SN, and therefore propose that the SN cluster constitute a suitable model to study in detail the morphological and functional relationships between neurons and glial cells in Anamnia.     

Behavior of delayed current under voltage clamp in the supramedullary neurons of puffer

Depolarizations applied to voltage-clamped cells bathed in the normal solution disclose an initial inward current followed by a delayed outward current. The maximum slope conductance for the peak initial current is about 30 times the leak conductance, but the maximum slope conductance for the delayed current is only about 10 times the leak conductance. During depolarizations for as long as 30 sec, the outward current does not maintain a steady level, but declines first exponentially with a time constant of about 6 msec; it then tends to increase for the next few seconds; finally, it declines slowly with a half-time of about 5 sec. Concomitant with the changes of the outward current, the membrane conductance changes, although virtually no change in electromotive force occurs. Thus, the changes in the membrane conductance represent two phases of K inactivation, one rapidly developing, the other slowly occurring, and a phase of K reactivation, which is interposed between the two inactivations. In isosmotic KCl solution after a conditioning hyperpolarization there occurs an increase in K permeability upon depolarization. When the depolarizations are maintained, the increase of K permeability undergoes changes similar to those observed in the normal medium. The significance of the K inactivation is discussed in relation to the after-potential of the nerve cells.     

Acid phosphatase activity in the supramedullary neurons of Coris julis (L.).

This work describes the acid phosphatase activity in supramedullary neurons of Coris julis, analyzed by a cytochemical method. The presence of both acid phosphatase-positive and -negative membrane bound granules indicates that only a part of the numerous electrodense granules in the supramedullary neurons can be interpreted as lysosomes. The great number of lysosomes in these large neurons of young animals is indicative of the rapid turnover of cell structures, which may be correlated with the high rate of synthesis. The electrodense granules showing no acid phosphatase activity are postulated to be vesicles containing gastrin/CCK-like peptide or precursors of this neuromediator.     

Ultrastructural features of somatostatin-containing neurons of the hypothalamus of rats with protein insufficiency

The electron microscopic investigation was performed to analyze somatostatin-contained nerve terminals in the median eminence of 21 days old malnourished rats' hypothalamus. In nerve terminals of malnourished animals in compared with controls ones there was found the increased density of granular vesicles (11.62 +/- 0.40 and 8.56 +/- 0.39 in 1 micron2, respectively) and decreased density of electron lucent vesicles with 120-160 nm diameter (1.66 +/- 0.18 and 3.43 +/- 0.26 in 1 micro2, respectively). The revealed increase in density of granular vesicles in axon terminals with positive immunohistochemical reaction to somatostatin in malnourished rats was explained by slow somatostatin release.     

Ultrastructural features of the human frontal cortex neurons of maturing and hydrocephalic cerebrum

Human frontal cortex neurons of hydrocephalic infants were studied with electron microscope. A number of maturing neurones exhibited shrinkage and increased electron density of cytoplasmic matrix in the midst of gross hydrocephalic interstitial oedema. Remarkable preservation of growth cones and arrays of microtubules in a few neuronal perikarya and axons were discernible. Rows of normal looking neurones with parallel arrays of cisternae of rough endoplasmic reticulum were also detected. Thus, preservation of significant number of neurones was apparent even in cases of extreme hydrocephalus.     

Ultrastructural features of chilling-injury in Episcia reptans

Abstract. Chilling the leaves of the extremely chill-sensitive plant Episcia reptans for only a few hours at 5°C causes ultrastructural changes such as swelling and disorganization of chloroplasts and mitochondria, and vesiculation of cytoplasmic membranes. Rewarming plants after 5–6 h chilling causes further deterioration in chloroplast and mitochondrial structure and the appearance of fibrous material in the cytoplasm of epidermal, mesophyll and vascular cells. The nature of the deposit is not known but it may be the cause of the rapid development of chilling-injury on return of plants to the warmth.     

DNA endoreplication in the clustered supramedullary neurons of the pufferfish Diodon holacanthus L. (osteichthyes)

DNA contents, ranging from 4C to more than 500C, were determined by a quantitative microfluorimetric assay in supramedullary neuron nuclei of the pufferfish Diodon holacanthus. The distribution of C values after ethidium bromide staining indicates an inter- and intra-individual variation in DNA contents which do not correspond to duplications of the total genome, suggesting that DNA replication is specific for particular genes (endoreplication). Moreover, the DNA content appears to be correlated with nuclear size. A relationship between the DNA amounts and the presence of AT- and GC-rich sequences has been shown.This work demonstrates, for the first time, DNA endoreplication in a specific neuronal type in vertebrates.     

Ultrastructural features of adult human tendon

Summary A variety of human tendons have been studied at the electron microscope level. The fibers of these tendons are composed of collagen fibrils that average 1,750 Å and 600 Å in diameter. A third population that measures 100 Å in diameter may represent immature collagen or filaments that are incorporated into tendon elastic fibers. The larger collagen fibrils vary in ratio with respect to one another, and are connected by interfibrillar bridges which in some cases appear to extend through the substance of the fibril. The collagen fibrils of the paratenon are less-well organized than those of the tendon proper and average 600 Å in diameter. Tendons that exhibit the property of lateral stretch (plantaris and palmaris) were compared at the ultrastructural level with tendons that do not have this property. No differences between the two tendon types could be determined in normal or spread preparations, indicating that the differences in physical characteristics are a result of fiber rather than fibril organization.Supported by Edward G. Schlieder Foundation GrantThe authors wish to thank Mrs. Janell Buck and Mrs. Eunice Schwartz for their excellent technical and secretarial assistance, and Mr. Garbis Kerimian for his excellent photographic work     

Ultrastructural features of Aloe ciliaris pollen

Summary Both the internal anatomy and the external morphology of the mature pollen grain of Aloe ciliaris have been studied, together with the cytological changes occurring during pollen activation. In mature pollen, the generative cell (GC) and the vegetative nucleus (VN) are closely associated with each other, and both can be found in the central part of the grain. In the generative cytoplasm, some organelles and microtubular bundles are present. In the vegetative cell, dictyosomes, stacks of rough endoplasmic reticulum, mitochondria, plastids, vacuoles, ribosomes, and masses of fibrillar material have been described. During pollen activation, important changes occur in both the generative and vegetative cells (VC). In the GC, the microtubular bundles become clearly visible, and the GC and VC gradually move towards the germ pore. The RER cisterns become free from the stacks, and organelles, such as dictyosomes, become very active. The fibrillar masses gradually decrease in number, and the individual fibrils become more evident and clearer in resolution.This research was carried out in the framework of contract no. BAP-0204-I of the Biotechnology Action Programme of the Commission of the European Communities     

Ultrastructural features of mitosis inLeishmania adleri

Summary The interphase nucleus ofLeishmania adleri has clumps of chromatin associated with the nuclear envelope and a large centrally located nucleolus. Prior to mitosis the basal bodies replicate at the cell anterior. Subsequently, dense plaques appear in the equatorial region of the nucleus at the time of spindle development. Microtubules appear in the nucleus adjacent to the nuclear envelope and embedded in the matrix of the plaques. A central spindle composed of a single bundle of microtubules develops and spans the nucleus. Plaques and nucleolar components laterally associate with the spindle and migrate towards the poles. The central spindle elongates to three to four times its original length separating the forming daughter nuclei and producing an interzonal spindle. A remnant of the interzonal spindle remains attached to each of the daughter nuclei until late into cytokinesis. The kinetoplast does not divide until after the completion of mitosis.