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.     

Ultrastructure of maturing fish (Oreochromis niloticus) and snake (Waglerophis merremii) erythroid cells with regard to hemoglobin biosynthesis

• 1.1. Fish and snake immature erythrocytes were submitted to a comparative ultrastructural study, analysing changes in organelles involved in hemoglobin (Hb) biosynthesis.
• 2.2. Iron uptake occurs probably via transferrin, and ferruginous compounds accumulate as siderosomes, taken as iron sources for heme biosynthesis, later on caught by a double lamella.
• 3.3. Mitochondrial membrane of the inner camera differentiates to lamellated bodies that, sucessively, give rise to expansions for ferruginous material and globin chains captation, constituting prehemosomal vesicles, which become condensed vesicles, followed by prohemosomes.
• 4.4. Through an internal membrane rearrangement, prohemosomes change to hemosomes wherein, hypothetically, heme and the globin chains assembly may occur.
• 5.5. In both fish and snake erythroid cells, all stages for hemosomegenesis are similar to the stages found in erythroid cells of other vertebrate species, including humans, except that fish cells often present single organelles of still unknown function, void of internal membrane.
• 6.6. Through electrophoresis of the respective supernatants obtained after osmotical lysis of the organellar fractions, it was shown that fish hemosomes contain three Hb patterns, while snake hemosomes present two patterns.

     

A relative morphological evaluation of hemoglobin biosynthesis in peripheral blood reticulocytes of normal and anemic rabbits

1. Peripheral blood reiculocytes of normal and bled rabbits and of rabbits with phenylhydrazine-induced anemia, were morphologically analysed, through silver sections, for a relative evaluation of hemoglobin (Hb) biosynthesis activity. 2. Reticulocytes of maturation degrees within the range of 35-60 polysomes/microns2, were compared as to their mean numbers of hemosomes (sites of heme integration into the globin chains), and mitochondria (indirect precursors for hemosome formation). 3. The results on the mean numbers of hemosomes per reticulocyte section, correlated to several physiological data under those three conditions, suggested a close relationship between Hb biosynthesis activity and hemosome frequency. 4. In bled rabbits, reticulocytes showing a low mean number of hemosomes (means hB/section = 0.32), as compared to reticulocytes of normal rabbits (means hN/section = 0.70) and to reticulocytes of rabbits with hemolytic anemia (means hH/section = 2.10), gave rise to a new erythrocyte population characterized by a low Hb content. 5. Hb concentration differences were verified by confronting hematological data before bleeding with those obtained after the regression of anemia.     

The alveolar epithelium of the newborn rat,and the significance of the osmiophilic lamellated bodies in cellular autophagy

Abstract

An attempt was made to determine the nature, origin, and fate of the membrane material of osmiophilic lamellated bodies, using lung tissue from neonate rats. The cytoplasm of the type II alveolar pneumonocyte contains centrioles, multivesicular bodies, and minute free vesicles similar to those in the multivesicular bodies. Autolysosomes, comprising membrane-bounded cytoplasmic regions and osmiophilic lamellated material, also occur in the type II pneumonocytes. The mitochondria often contain concentric membrane accumulations and membranous whorls. The type II alveolar cells are characterised by an intensive autophagy; this is apparently correlated with glycogenolysis, and with a radical cytodifferentiation by which the cells transform to the type I pneumonocyte. The osmiophilic lamellae of the autolysosomes are probably emptied isolation membranes. The mitochondria possibly serve as repositories for the massive membrane accumulations remaining after cytoplasmic lysis, which may invaginate into the organelles. The osmiophilic lamellated bodies typical of type II alveolar pneumonocytes may be mitochondrial membranes packed with the residual membranous material. Myeloid matter in the alveolar spaces (derived from the osmiophilic lamellated bodies) is best interpreted, not as an organised secretory product, but rather as a residue of cellular autophagy.     

Structural studies on lamellated osmiophilic bodies isolated from pig lung. 31P NMR results and water content

1. Lamellated osmiophilic bodies are intracellular organelles in which pulmonary surfactant is stored prior to secretion. They contain about 85% phospholipid (per dry weight) and dipalmitoyl phosphatidylcholine is a major constituent, and although their ultrastructure is uncertain it is generally supposed that they resemble liposomes. However, liposomes are stable because layers of water are interposed between the lipid bilayers whereas an essential aspect of the function of lamellated bodies is that, subsequent to their secretion, they are rapidly disrupted to form a surface-active film which covers the respiratory epithelium of the lung. 2. A new method for isolating lamellated bodies from pig lung is described which has the advantage of speed and simplicity and which results in increased yields. The homogeneity of the preparation is similar to that obtained by other methods. 3. 31P NMR spectra of lamellated bodies showed that at 40 degrees C about 95% of the phospholipid was present as extended bilayers and that about 5% was present in a phase exhibiting isotropic head group mobility (tau R less than 10(-5) s). It is suggested that this phase may be due to apolar proteins which are present both in lamellated bodies and in liposomes prepared from lipids extracted from them. 4. The internal water content of lamellated bodies has been measured gravimetrically and the hydration of the phospholipid head groups has been examined by 31P NMR. The two methods gave results in good agreement and show that there are about seven molecules of water/molecule of phospholipid. It is concluded that although the phospholipid head groups in lamellated bodies are fully hydrated, there is no zone of free water. 5. Lamellated bodies are osmotically insensitive to NaCl whereas liposomes prepared from lipids extracted from them behave like perfect osmometers. It is suggested that the osmotic insensitivity and restricted water content of lamellated bodies are important to their function and dependent upon polar proteins in the outer limiting membrane.     

Immunocytochemical mapping of the hemoglobin biosynthesis site in amphibian erythroid cells.

During the past 25 years, several studies have attempted to determine the site of integration of the heme and the four globin chains in vertebrate erythroid cells that is important in the formation of the hemoglobin molecule. Mitochondrion-like organelles or hemosomes were pointed out as responsible for this task. We performed several experiments to investigate this hypothesis. The intracellular distribution of hemoglobin in amphibian erythroid cells was detected by post-embedding immuno-electron microscopy, using a polyclonal anti-human hemoglobin-proteinA-gold complex. Hemoglobin mapping showed an intense labeling in the cell cytoplasm, but none in cytoplasmic structures such as endoplasmic reticulum, mitochondria, mitochondrion-like organelles, Golgi complex, ribosomes or ferruginous inclusions. The mitochondrial fraction obtained according to the protocol described for some authors, showed by ultrastructural examination that this fraction has a heterogeneous content, also composed by microvesicles rich in cytoplasmic hemoglobin, an artifact generated by mechanical action during cell fractionation. Thus, when this fraction is lysed and its content submitted to electrophoresis, hemoglobin bands would be found inevitably, causing false-positive results, erroneously attributed to hemoglobin content of mitochondrion-like organelles. Our data do not confirm the hypothesis that the final hemoglobin biosynthesis occurs inside mitochondrion-like organelles. They suggest that the hemoglobin molecule be assembled in the erythrocyte cytoplasm outside of mitochondria or hemosomes.     

Lipid peroxidation in hemoglobin-containing liposomes. Effects of membrane phospholipid composition and cholesterol content

The effects of phospholipid-oxidation state and vesicle composition on lipid peroxidation in hemolysate-containing liposomes (hemosomes) were studied by the thiobarbituric acid assay. Liposomes (hemosomes) were prepared from egg phosphatidylcholine (PC) with either low (PC0.08) or high (PC0.66) oxidation indices reflecting low and high conjugated diene/lipid hydroperoxy contents. Thiobarbituric acid reactivity was negligible over 6 h at 38 degrees C in buffer-containing (control) liposomes prepared from PC0.08, whereas it was slightly increased in those prepared from PC0.66. Encapsulated hemolysate had no effect in PC0.08 liposomes, but significantly increased thiobarbituric acid reactivity in those prepared from PC0.66. Inclusion of either phosphatidylethanolamine or phosphatidylinositol in the membrane further increased lipid peroxidation in hemosomes prepared from PC0.66, whereas phosphatidic acid and phosphatidylserine were inhibitory. Inclusion of cholesterol in the membrane had no effect in PC0.66 hemosomes, but significantly inhibited lipid peroxidation in the presence of phosphatidylethanolamine or phosphatidylinositol. The effects of phosphatidic acid and cholesterol were dose-dependent. Co-incorporation of cholesterol and phosphatidic acid or phosphatidylserine in the membrane resulted in almost complete elimination of hemoglobin (Hb)-induced lipid peroxidation. Lysophosphatidic acid had similar effect as phosphatidic acid, whereas lysophosphatidylserine exerted inhibition only in the presence of phosphatidylethanolamine. The rate of lipid peroxidation showed no correlation with the amount of encapsulated Hb, neither with the oxidation indices nor the polyunsaturated fatty acid contents of negatively charged phospholipids. The above findings suggest a possible role for the high cholesterol content and preferential localization of phosphatidylserine in the inner bilayer leaflet of erythrocyte membrane in protecting against Hb-induced lipid peroxidation in the membrane.     

Acetylation of human fetal hemoglobin occurs throughout erythroid cell maturation

The biosynthesis of human acetylated fetal hemoglobin (Hb F1) has been examined by incubating the following cell types with [3H]leucine: (a) burst-forming unit erythroid cells cultured from umbilical cord mononuclear cells, (b) infant bone marrow, (c) umbilical cord blood, and (d) peripheral blood cells from adults with elevated fetal hemoglobin. Newly synthesized Hb F1 was 18-20% that of Hb F0 in burst-forming unit erythroid cells which were immature, mature, or in an intermediate state of development. In infant marrow and in infant and adult peripheral blood the extant Hb F1 comprised 10.8 +/- 1.8% of the total Hb F. In marrow cells the specific radioactivity (cpm/mg) of Hb F1 was 1.4-2.0-times greater than that of Hb F0. In peripheral blood cells these ratios were slightly greater. [3H]Leucine-labeled infant bone marrow, umbilical cord blood, and adult peripheral blood cells were subjected to density gradient ultracentrifugation. The ratios of specific radioactivity for Hb F1/Hb F0 increased from 1.0-1.8 in the lightest cell zone to 5.2-9.0 in the more dense cells. Thus the biosynthesis of Hb F1 is enhanced in cells which are more mature than those responsible for the bulk of hemoglobin synthesis, and the acetylation of Hb F provides a marker of erythroid cell maturation.     

Oxidation and denaturation of hemoglobin encapsulated in liposomes

A study was made of the in vitro stability of hemoglobin-containing liposomes (‘hemosomes’) prepared from phosphatidylcholines, equimolar cholesterol and red cell lysate by the hand-shaking and ether-injection methods. Absorption spectra indicated hemichrome formation in ‘hemosomes’ prepared by the ether-injection technique, and increased oxidation of hemoglobin in hand-shaken ‘hemosomes’. The denaturation of hemoglobin in ether-injection ‘hemosomes’ was increased if the initial methemoglobin content of the hemolysate, or the temperature of preparation was elevated. It was slower if liposomes were prepared under either N₂ or CO, or if the radical scavenger 1,3-diphenylisobenzofuran was added with the ether. Egg phosphatidylcholine and synthetic saturated phospholipids gave the same results. With hand-shaken ‘hemosomes’ the oxidized product was primarily methemoglobin, and oxidation could be inhibited by using saturated phosphatidylcholines instead of egg phosphatidylcholine. Lysophosphatidylcholine levels were higher and arachidonic acid levels lower in egg phosphatidylcholine ‘hemosomes’ than in equivalent liposomes containing no hemolysate. The ‘hemosome’ seems to be a suitable model for the study of hemoglobin-lipid membrane interactions and the resulting hemoglobin denaturation process.     

Differentiation of the tegument and associated structures in Diphyllobothrium dendriticum Nitsch (1824) (Cestoda: Pseudophyllidea). An electron microscopical study

Grammeltvedt Anne-François 1973. Differentiation of the tegument and associated structures in Diphyllobothrium dendriticum Nitsch 1824 (Cestoda : Pseudophyllidea). An electron microscopical study. International Journal for Parasitology3: 321–327. The differentiation of the tegument and associated structures of the coracidium, procercoid, plerocercoid and adult is described. The embryophore is composed of four zones and is covered by a fibrous layer resembling a glycocalyx. The oncospheral plasma membrane is extensively folded. A typical cestode tegument, with a distal and perinuclear cytoplasm, is probably already existing in the coracidium. The formation of the microvilli starts after about three days in the copepod host. In young procercoids ribosomes and Golgi complexes were observed in the distal cytoplasm. These organelles disappear at later stages. The infective procercoid has a typical tegument. The microvilli are shaped like a thorn compressed from the sides. They have an electron dense tip and a less dense base in which microfilaments are seen. Bodies, called disc-shaped and lamellated bodies, are described. The microvilli of the plerocercoid are characterized by a great variation in shape. The villi are bounded by two unit membranes. The lamellated bodies are especially well developed. The adult microvilli are uniform in shape. The lamellated bodies are few in young adults and disappear in mature worms.     

Ultrastructure of the Lamellated Cytoplasmic Inclusions in Schwann Cells of the Marine Nematode,Deontostoma californicum

Electron microscopy of the photoreceptors in the marine nematode, Deontostoma californicum, revealed numerous lamellated inclusions in the Schwann cells ensheathing the lateral cephalic nerves. Immediately after the axons from the modified bipolar neurons of the photoreceptors enter the lateral nerves, these spherical-to-oval lamellated bodies are observed in the surrounding Schwann cell cytoplasm. These previously undescribed Schwann cell inclusions, approximately 500 nm long and 320 nm in diameter, are lamellated and characterized by the presence of an electron-dense stalk-like process, 80-280 nm long. The lamellated inclusions are bound by a single limiting membrane, 6-7 nm thick, which shows occasional interruptions. The internal structure of the inclusions is characterized by the presence of electron-dense lamellae or bands, 11-16 nm thick, which assume various complex patterns ranging from arrays of parallel linear densities to a reticulate appearance. In addition, the nematode Schwann cell cytoplasm contains the usual organelles, gliosome- and lysosome-like inclusions. Their relationship with lipofuscin pigments is briefly discussed.     

Primitive erythropoiesis in early chick embryogenesis. II. Correlation between hemoglobin synthesis and the mitotic history

Primitive erythroblasts in the circulating blood of the chick embryo continue to divide while synthesizing hemoglobin (Hb). Hb measurements on successive generations of erythroblasts show that there is a progressive increase in the Hb content of both interphase and metaphase cells. Furthermore, for any given embryo the Hb content of metaphase cells is always significantly greater than that of interphase cells. The distribution of Hb values for metaphase cells suggests that there are six Hb classes corresponding to the number of cell cycles in the proliferative phase. The location of erythroblasts in the cell cycle was determined by combining Feulgen cytophotometry with thymidine radioautography on the same cells. Measurements of the Hb content for erythroblasts in different compartments of the cell cycle (G1, S, G2, and M) show a progressive increase through the cycle. Thus, the amount of Hb per cell is a function of the number of cell divisions since the initiation of Hb synthesis and, to a lesser degree, the stage of the cell cycle. Earlier generations of erythroblasts synthesize Hb at a faster rate than the terminal generation. Several models have been proposed to explain these findings.     

Embryogenesis and germination in rye (Secale cereale L.)

Summary When rye embryos imbibe water they rapidly return to a condition of biochemical and structural complexity. Three stages of imbibition can be recognised: Phase I a short period (10 min) of physical wetting; Phase II a longer period (1 h) when little further imbibition occurs, followed by Phase III a continuous phase of active water uptake. The latter coincides with an increase in respiration rate and an increase both in the number of mitochondria and of cristae within them. Changes in fine structure become evident in all organelles in Phase III, after 2 h of imbibition. In the unimbibed embryo endoplasmic reticulum is present only as short crescents associated with electron lucent bodies, but in Phase III the endoplasmic reticulum proliferates to form many surrounding cirlets. After 6 h these circlets become fewer and instead the endoplasmic reticulum is seen in close association with the nuclear membrane. Concurrently incorporation of radioactive uridine and thymidine is first detectible. This suggests that the large increase in protein synthesis occurs on new ribosomes present on the reticulum associated with the nuclear membrane. For the first 6 h protein synthesis must occur either on polysomes within the dense packing of ribosomes or on these circlets of endoplasmic reticulum associated with electron lucent bodies.     

Structural correlates of cytoplasmic and chloroplast lipid body synthesis in Chlamydomonas reinhardtii and stimulation of lipid body production with acetate boost

Light microscopy and deep-etch electron microscopy were used to visualize triacylglyceride (TAG)-filled lipid bodies (LBs) of the green eukaryotic soil alga Chlamydomonas reinhardtii, a model organism for biodiesel production. Cells growing in nitrogen-replete media contain small cytoplasmic lipid bodies (α-cyto-LBs) and small chloroplast plastoglobules. When starved for N, β-cyto-LB formation is massively stimulated. β-Cyto-LBs are intimately associated with both the endoplasmic reticulum membrane and the outer membrane of the chloroplast envelope, suggesting a model for the active participation of both organelles in β-cyto-LB biosynthesis and packaging. When sta6 mutant cells, blocked in starch biosynthesis, are N starved, they produce β-cyto-LBs and also chloroplast LBs (cpst-LBs) that are at least 10 times larger than plastoglobules and eventually engorge the chloroplast stroma. Production of β-cyto-LBs and cpst-LBs under the conditions we used is dependent on exogenous 20 mM acetate. We propose that the greater TAG yields reported for N-starved sta6 cells can be attributed to the strain's ability to produce cpst-LBs, a capacity that is lost when the mutant is complemented by a STA6 transgene. Provision of a 20 mM acetate "boost" during N starvation generates sta6 cells that become so engorged with LBs-at the expense of cytoplasm and most organelles-that they float on water even when centrifuged. This property could be a desirable feature for algal harvesting during biodiesel production.     

Metamorphosis in Tokophrya infusionum; an Electron-Microscope Study

SYNOPSIS. In Tokophrya infusionum metamorphosis from a ciliated swimming embryo to a sessile organism with a stalk, disc, and tentacles lasts only 3 minutes. The remarkable speed of meta-morphosis was clarified by an electron-microscope study of embryos before and during metamorphosis. Ultrathin sections have revealed that the embryo has at the anterior end of the body a number of specialized structures, such as dense bodies containing the precursor material for the disc and stalk, and microtubules which align the dense bodies into rows leading to pit-kite invaginations of the pellicle at the tip of the anterior end. At meta-morphosis the embryo settles down on this end and the precursor material is released thru the pits to the outside. At the same time the body of the embryo invaginates at this end, forming a cavity which becomes deeper and narrower until it acquires the shape of a channel. The 1st drops released from the dense bodies spread out on the substrate, forming the disc. The rest of the material, secreted into the channel, solidifies there to form the stalk. It seems obvious that the channel serves as a mold for the stalk, since after completion of the stalk the channel disappears. The stalk is structureless with no limiting membrane; it is outside the boundaries of the cell. Both the stalk and disc are extra-cellular organelles.
Of the new organelles appearing at metamorphosis, only the stalk and disc are formed de novo. The electron-microscope study disclosed that the embryo has internal parts of tentacles composed of a tube formed of microtubules. At the distal end of the microtubules is a ring of dense material. During metamorphosis the microtubules, together with the dense ring, grow out of the body, and along with them the pellicle and plasma membrane to form the external part of the tentacle.     

The role of osmiophilic bodies and Pfg377 expression in female gametocyte emergence and mosquito infectivity in the human malaria parasite Plasmodium falciparum

Osmiophilic bodies are membrane-bound vesicles, found predominantly in Plasmodium female gametocytes, that become progressively more abundant as the gametocyte reaches full maturity. These vesicles lie beneath the subpellicular membrane of the gametocyte, and the release of their contents into the parasitophorous vacuole has been postulated to aid in the escape of gametocytes from the erythrocyte after ingestion by the mosquito. Currently, the only protein known to be associated with osmiophilic bodies in Plasmodium falciparum is Pfg377, a gametocyte-specific protein expressed at the onset of osmiophilic body development. Here we show by targeted gene disruption that Pfg377 plays a fundamental role in the formation of these organelles, and that female gametocytes lacking the full complement of osmiophilic bodies are significantly less efficient both in vitro and in vivo in their emergence from the erythrocytes upon induction of gametogenesis, a process whose timing is critical for fertilization with the short-lived male gamete. This reduced efficiency of emergence explains the significant defect in oocyst formation in mosquitoes fed blood meals containing Pfg377-negative gametocytes, resulting in an almost complete blockade of infection.     

Inclusion bodies in loggerhead erythrocytes are associated with unstable hemoglobin and resemble human Heinz bodies

The aim of this study was to clarify the role of the erythrocyte inclusions found during the hematological screening of loggerhead population of the Mediterranean Sea. We studied the erythrocyte inclusions in blood specimens collected from six juvenile and nine adult specimens of the loggerhead turtle, Caretta caretta, from the Adriatic and Tyrrhenian Seas. Our study indicates that the percentage of mature erythrocytes containing inclusions ranged from 3 to 82%. Each erythrocyte contained only one round inclusion body. Inclusion bodies stained with May Grünwald-Giemsa show that their cytochemical and ultrastructure characteristics are identical to those of human Heinz bodies. Because Heinz bodies originate from the precipitation of unstable hemoglobin (Hb) and cause globular osmotic resistance to increase, we analyzed loggerhead Hb using electrophoresis and high-performance liquid chromatography to detect and quantitate Hb fractions. We also tested the resistance of Hb to alkaline pH, heat, isopropanol denaturation, and globular osmosis. Our hemogram results excluded the occurrence of any infection, which could be associated with an inclusion body, in all the specimens. Negative Feulgen staining indicated that the inclusion bodies are not derived from DNA fragmentation. We hypothesize that amino acid substitutions could explain why loggerhead Hb precipitates under normal physiologic conditions, forming Heinz bodies. The identification of inclusion bodies in loggerhead erythrocytes allow us to better understand the haematological characteristics and the physiology of these ancient reptiles, thus aiding efforts to conserve such an endangered species.     

Hemoglobin-mediated selenium export from red blood cells

On the basis of the fact that selenium from selenite binds to hemoglobin (Hb), we investigated the missing process in the selenium export from red blood cells (RBCs), i.e., the transfer of selenium bound to Hb to RBC membrane proteins. To elucidate the molecular events of the Hb-associated selenium export from RBC, a Hb–Se complex was synthesized from thiol-exchange of Cys-β93 in Hb with penicillamine-substituted glutathione selenotrisulfide, as a model of major metabolic intermediates, and then interactions between the Hb–Se complex and RBC inside-out vesicles (IOVs) were examined. Selenium bound to Hb was transferred to the IOV membrane on the basis of the intrinsic interactions between Hb and the cytoplasmic domains of band 3 protein (CDB3). The observed selenium transfer was inhibited by the pretreatments of IOVs with iodoacetamide and the α-chymotrypsin digestion, indicating that the Hb mediates the selenium transfer to the thiol groups of CDB3. In addition, it was found that deoxygenated Hb, with a high binding affinity for CDB3, more favorably transferred selenium to the IOV membranes than oxygenated Hb, with a low affinity. When selenium export from RBC to the plasma was examined by continuously introducing nitrogen gas, the selenium export rate was promoted with an increase in the rate of deoxygenated Hb. Overall, these data suggested that Hb could possibly play a role in the selenium export from RBC treated with selenite in an oxygen-linked fashion. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

去甲痛上腺素在大鼠缰核引起的心血管效应及其机制

Cardiovascular effect of norepinephrine (NE) in the habenular nucleus (Hb) and the underlying mechanism were investigated in urethane-anesthetized rats. NE microinjection into Hb produced a dose-dependent increase in mean arterial blood pressure and heart rate, an effect that could be attenuated by the pretreatment in Hb with alpha-receptor blocker phentolamine, but not by the pretreatment with beta-receptor blocker propranolol or physiological saline. Microinjection of kainic acid into Hb gave rise to a marked increase in mean arterial blood pressure and heart rate, but microinjection of lidocaine did not elicit significant cardiovascular effect. The above results suggest that NE in Hb plays an important role in cardiovascular control as a result of Hb excitation through activation of alpha-receptor.