Study of the integument that covering back and stinger of the freshwater stingray Potamotrygon rex (Chondricthyes, Potamotrygonidae).

The objective of this study was to describe the histology and histochemistry of the integument covering the back and stinger of the freshwater stingray Potamotrygon rex, endemic to the Middle Upper Tocantins River. The species has a dark back and yellowish circular spots that extend to the tail, which has one to two stings located in the median portion of the tail. Through histological study it was observed that the epithelia of the back and stinger are composed of non-keratinized stratified pavement epithelial tissue, and are organized in three layers: basal, intermediate and superficial. The differences between the tissues are related to the cell types that compose them. The back is organized with epithelial cells, mucus cells, granulocyte cells and chromatophores. The mucus cells are distributed in different layers along the animal's back, influencing the thickness of the tissue. The tissue that covers the stinger is composed of epithelial cells, chromatophores and specialized cells in protein synthesis. In the histochemistry, the stinger epithelial cells were stained with Bromophenol Blue, especially those of the intermediate layer, which were called specialized cells. In the back the epithelial cells were stained with Bromophenol Blue, Alcian Blue and PAS, and the mucous cells with PAS. In both tissues the presence of protein reserves was detected, areas so called because they are stained strongly with Bromophenol Blue. The results show that the stinger presents activity directed to the production of proteins, and that the back is organized to produce different components, which constitute the cuticle that covers the animal's body.

Hyperproliferative action of bovine papillomavirus: genetic and histopathological aspects.

The bovine papillomavirus (BPV) causes papillomas that regress spontaneously, but can also progress to malignancy. This study evaluated the role of BPV in oncogenesis. Twenty-four samples from uninfected calves and the papillomas of BPV infected cattle were subjected to molecular diagnosis, as well as histopathological and immunohistochemical analyses. The comet assay (CA) was used to evaluate the clastogenic potential of BPV. The results confirmed the presence of BPV-2, 3, 5, and 9 in infected samples. Histopathological analysis revealed acanthosis, koilocytosis, hypergranulosis, hyperkeratosis, and transformed fibroblasts.E7 and L1 BPV proteins were detected in the epithelium, as well as in the connective tissues, indicating productive infection at different sites. CA results showed that BPV-2, 5, and 9 exhibit the same level of clastogenicity. These findings support the oncogenic action of BPV in establishing a favorable microenvironment for oncogenesis.

Bovine papillomavirus in beef cattle: first description of BPV-12 and putative type BAPV8 in Brazil.

Bovine papillomavirus (BPV) is an oncogenic virus associated with benign and malignant lesions, which result in notable economic losses. Peripheral blood samples and cutaneous papillomas were obtained from four adult beef cattle. Viral molecular identification was performed using specific primers for BPV-1, -2 and -4 in blood diagnosis and FAP59/FAP64 for skin papillomas. Histopathologic examination was done as a complementary and differential diagnosis. The fragments were purified, sequenced, and compared using BLASTn. The blood diagnosis showed the presence of BPV-2 and the analysis of cutaneous papillomas showed the presence of BPV-4, a new putative virus type BAPV8, and BPV-12, revealing for the first time the presence of BPV-12 and the putative type BAPV8 in beef cattle in Brazil. The sequences were deposited in the GenBank. Histopathology revealed acanthosis, hyperkeratosis, and koilocytosis in all samples analyzed. The presence of BAPV8 and BPV-12 in Brazil emphasizes the ubiquitous dissemination of BPVs in the herds of Brazil.

Vimentin is synthesized by mouse vascular trophoblast giant cells from embryonic day 7.5 onwards and is a characteristic factor of these cells.

INTRODUCTION: A few days after implantation, the embryo grows intensely and trophoblast giant cells (TGC) undergo cell rearrangement, especially of their cytoskeleton. Although we previously showed vimentin in mouse antimesometrial TGC at embryonic days (E) 8.5-10.5, by immunostaining, we did not demonstrate what is the first embryonic day that TGC synthesize vimentin and whether mouse chorioallantoic placental TGC express vimentin. This is of particular interest because cytokeratin is a marker for TGC in the placenta. METHODS: We performed in situ hybridization and immunolocalization, combined with histological and stereological techniques, to study vimentin expression between E6.5 and E12.5 and we investigated Vegf and Flt1/Vegfr1 expression in TGC. RESULTS: Analyses of morphologic parameters of TGC showed that the highest expansion of nuclear and cytoplasmic volumes (p ≤ 0.05) occurred at E7.5. We detected vimentin expression in TGC from E7.5 onwards; vimentin disappeared as TGC degeneration advanced. Primary and secondary TGC showed intense positive immunostaining for vimentin, Vegf and Flt1/Vegfr1 at E7.5. In the chorioallantoic placenta, parietal TGC (zone of giant cells), spiral artery-associated TGC, maternal blood canal-associated TGC and TGC within the sinusoidal spaces of the labyrinth exhibited an intense immunopositive-reaction for vimentin. DISCUSSION: At E7.5 TGC acquire vimentin, Vegf and Flt1/Vegfr1; at the same time, blood begins to drain from maternal vessels. Vimentin synthesis initiates during a differentiation process of TGC and continues throughout the stage of vascular TGC. CONCLUSIONS: We propose that vimentin is a characteristic factor of specialized (vascular) TGC, being a valuable tool for studying pathological pregnancies associated with defects in vascular trophoblasts in mice.

Haematopoiesis in snakes (Ophidia) in early postnatal development.

The occurrence of haematopoiesis has been studied in various parts of the spine and in the ribs in four species of snakes (Boa constrictor L., Elaphe guttata L., Lamprophis fulaginosus Boie., Bothrops jararaca Wied.) from hatching until 150 days of postnatal development. Marrow spaces are formed by chondrolysis with various time frames depending on the studied species. Marrow cells egress to the general circulation in two ways: via migration through the endothelial cells lining the venous sinuses or by the rupture of protrusions. Erythroblasts are present in the lumen of marrow sinuses suggesting their final maturation there. Various relationships of the spleen to the pancreas have been found. No myelopoietic foci occur in the spleen, liver or kidney of any of the studied species. However, erythropoiesis (sparse islets) has been observed in Bothrops jararaca spleen.

Hematopoiesis in snakes (Ophidia).

Locations of the hematopoietic tissue have been described in the following ophidian species: Bothrops jararaca, Bothrops jararacusu, Waglerophis merremii, Elaphe teniura teniura, Boa constrictor, and Python reticulatus. Studies were carried out on perfusion fixed vertebrae, ribs, spleen, liver, thymus, and kidney. Routine histological technique was applied using both light and electron microscopy. Hematopoietic tissue was found in the following locations of the vertebrae: neural spine, neural arch, postzygophysis processes, hypapophysis, vertebral centre. Moreover, intense hematopoiesis was found inside the ribs. In the spleen and thymus, only lymphopoiesis was found. Hematopoietic islets in the spleen were sporadically found only in young specimens. No hematopoiesis was observed in the liver and kidney. In the studied species, there were no differences in the location of hematopoietic tissue. A new model of mature and immature blood cell release to the lumen of marrow sinuses different from that known to operate in higher vertebrates is proposed.

Acute food restriction increases collagen breakdown and phagocytosis by mature decidual cells of mice.

An ultrastructural study was undertaken on antimesometrial mature decidual tissue of fed and food-restricted mice, on day 9 of pregnancy. The mean ad libitum food intake was established on mice from the 8th till the 9th day of pregnancy. Fed mice were used as controls. Experimental animals were divided into two groups: one was allowed to feed 25% of normal diet and the other 50%. Extracellular collagen fibrils were scarce in fed animals and conspicuous in food restriction. Granular electron-dense deposits and filamentous aggregates of disintegrating collagen fibrils were observed in all food-deprived mice but were rarely noted in fed animals. Intracellular vacuolar structures exhibited other typical cross-banded collagen immersed in finely granular electron-translucent material (clear vacuole) or electron-dense material containing collagen fibrils with a faint periodicity (dark vacuole). The clear and dark vacuoles were scarce in fed animals and evident in food-restricted mice, mainly in those 25% food restricted. Although collagen breakdown may be part of the normal process of decidual tissue remodelling our results suggest that it is enhanced in food-restricted animals. Thus it seems that collagen breakdown is a normal mechanism that may be regulated by the food intake of the pregnant animal.

Hemosomegenesis and hemoglobin biosynthesis in vertebrates.

1. Ultrastructural observations on maturing rabbit embryo erythroid cells led to the finding of hemoglobinized organelles distinguishable from mitochondria due to their highly dense matrix, two or three longitudinally arranged double lamellae, and smaller diameters. Intraorganellar 50-60 A particles identical to those contained in the hemoglobinized cytoplasm were found. 2. Their hemoglobin (Hb) content was demonstrated by electrophoresis of the concentrated supernatant from the isolated, washed, and osmotically lysed organellar fraction. We have proposed that these organelles are the sites for heme integration into the globin (G) polypeptide chains and subunits assembly. The term hemosome has been suggested for such entities. 3. This hypothesis has been sustained by several analytical and experimental works based on the postulation that hemosomes should be found at higher frequencies where the Hb biosynthesis rate is more intensive, or where the induction of this biosynthesis is always dependent on the formation of hemosomes. 4. Maturing erythroid cells of the circulating embryo blood contain hemosomes in higher frequency than in liver erythroid cells, coinciding with the higher Hb biosynthesis rate in peripheral blood than in the liver. In bleeding anemia, the decay of Hb concentration parallels the reduction of the mean number of hemosomes per reticulocyte, in comparison with normal reticulocytes. 5. In HeLa cells and epithelial cultured cells induced to synthesize Hb, it was shown that this biosynthesis is ever concomitant with the formation of hemosomes and depends on the presence of erythropoietin, as occurs in erythroid cells. 6. Studies on hemosomegenesis and Hb biosynthesis experimentally effected in epithelial cultured cells, allowed the interpretation of the sequence of events leading to hemosome formation in maturing erythroid cells. Simultaneously with iron uptake, mitochondria differentiate to lamellated bodies and, successively, expansions rise for ferruginous compounds and G polypeptides gathering, followed by prehemosome vesicles formation, which condense and change to prohemosomes that afterwards evolve to hemosomes. 7. These dynamics, and organellar Hb have been detected in immature erythrocytes of mammalians, including humans, avians, reptilians, amphibians and representative fish specimens. It appears that these events occur in the erythrocytary maturation of all vertebrate classes.

Hemoglobin biosynthesis enhancement following mitochondrial membrane growth and differentiation.

1. A quantitative increase of organelles in early reticulocytes has been observed compared to that found in late erythroblasts of the peripheral rabbit embryo blood. 2. The increase is due to the formation of hemosomes, organelles taken as sites for final hemoglobin (Hb) biosynthesis or where the assembly of heme and globin polypeptides could occur. 3. These organelles derive indirectly from mitochondria whose internal membrane grows concomitantly to its differentiation, originating lamellated bodies that modify successively to prehemosomal vesicles, prohemosomes and hemosomes. 4. The occurrence of membrane synthesis for the formation of lamellated bodies could explain the increase of organelles per cell and, thereby, the enhancement of the Hb biosynthesis rate in peripheral embryo blood in relation to this biosynthesis rate in the liver, as had been biochemically ascertained by other authors.

Comparative ultrastructure of maturing toad (Bufo ictericus) and rabbit (Oryctolagus cuniculus) erythroid cells with regard to hemoglobin biosynthesis.

1. Toad and rabbit maturing erythroid cells were comparatively analysed with regard to their ultrastructural modifications involved in hemoglobin (Hb) biosynthesis. 2. The mitochondrial inner membrane differentiates to a lamellated body that, successively, gives rise to prehemosomal vesicles, prohemosomes, and to hemoglobinized organelles called hemosomes. 3. The prehemosomal vesicle involves ferruginous inclusions, taken as iron sources for heme biosynthesis, as well as the polypeptide globin chains, assembling themselves in the course of volume reduction. 4. From the prohemosomal stage onwards, where possibly heme biosynthesis occurs, hemosomes are formed; these organelles are presumably sites where the final Hb biosynthesis could take place. 5. All development stages leading to hemosome formation are similar in toad and rabbit erythroid cells, except that, in the toad, the structural prohemosome characteristics persist in hemosomes. 6. Through toad erythroid cell fractionation and electrophoresis of the organelle lysate supernatant, a wide and a weak cytoplasmic Hb bands were obtained; the latter coincides with the intraorganellar Hb band.

Mitochondria, hemosomes and hemoglobin biosynthesis.

Erythroid cells of the liver and peripheral blood of rabbit embryos, as welt of bone-marrow and peripheral blood of adult rabbits with phenylhydrazine-induced hemolytic anemia, were analysed ultrastructurally to investigate the formation of hemosomes, organelles suggested to be sites of heme integration into the four globin polypeptides. After the incorporation of iron-containing material, free ferruginous inclusions appear. Mitochondria apparently give rise to lamellated bodies whose double lamellae expand for the captation of the ferruginous inclusions, a source of iron for heme synthesis, and globin polypeptidic chains already synthesized in the diffusely distributed polysomes. The expanding lamellae return, so that prehemosomal vesicles containing ferruginous material and globin are formed. Through invaginations of the inner membrane and a possible rotational movement of these vesicles the beginning of prohemosome formation takes place concomitant with the occurrence of heme synthesis. A structural rearrangement of prohemosomes occurs, and typical hemosomes containing hemoglobin molecules develop, whose content spreads throughout the cytoplasm by disruption of the organelle membranes.