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.

     

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.     

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.     

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.     

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.     

Carbon monoxide induced erythroid differentiation of K562 cells mimics the central macrophage milieu in erythroblastic islands

Growing evidence supports the role of erythroblastic islands (EI) as microenvironmental niches within bone marrow (BM), where cell-cell attachments are suggested as crucial for erythroid maturation. The inducible form of the enzyme heme oxygenase, HO-1, which conducts heme degradation, is absent in erythroblasts where hemoglobin (Hb) is synthesized. Yet, the central macrophage, which retains high HO-1 activity, might be suitable to take over degradation of extra, harmful, Hb heme. Of these enzymatic products, only the hydrophobic gas molecule - CO can transfer from the macrophage to surrounding erythroblasts directly via their tightly attached membranes in the terminal differentiation stage.Based on the above, the study hypothesized CO to have a role in erythroid maturation. Thus, the effect of CO gas as a potential erythroid differentiation inducer on the common model for erythroid progenitors, K562 cells, was explored. Cells were kept under oxygen lacking environment to mimic BM conditions. Nitrogen anaerobic atmosphere (N₂A) served as control for CO atmosphere (COA). Under both atmospheres cells proliferation ceased: in N₂A due to cell death, while in COA as a result of erythroid differentiation. Maturation was evaluated by increased glycophorin A expression and Hb concentration. Addition of 1%CO only to N₂A, was adequate for maintaining cell viability. Yet, the average Hb concentration was low as compared to COA. This was validated to be the outcome of diversified maturation stages of the progenitor''s population.In fact, the above scenario mimics the in vivo EI conditions, where at any given moment only a minute portion of the progenitors proceeds into terminal differentiation. Hence, this model might provide a basis for further molecular investigations of the EI structure/function relationship.     

Biosynthesis of heme in immature erythroid cells. The regulatory step for heme formation in the human erythron

Heme formation in reticulocytes from rabbits and rodents is subject to end product negative feedback regulation: intracellular "free" heme has been shown to control acquisition of transferrin iron for heme synthesis. To identify the site of control of heme biosynthesis in the human erythron, immature erythroid cells were obtained from peripheral blood and aspirated bone marrow. After incubation with human 59Fe transferrin, 2-[14C]glycine, or 4-[14C]delta-aminolevulinate, isotopic incorporation into extracted heme was determined. Addition of cycloheximide to increase endogenous free heme, reduced incorporation of labeled glycine and iron but not delta-aminolevulinate into cell heme. Incorporation of glycine and iron was also sensitive to inhibition by exogenous hematin (Ki, 30 and 45 microM, respectively) i.e. at concentrations in the range which affect cell-free protein synthesis in reticulocyte lysates. Hematin treatment rapidly diminished incorporation of intracellular 59Fe into heme by human erythroid cells but assimilation of 4-[14C]delta-aminolevulinate into heme was insensitive to inhibition by hematin (Ki greater than 100 microM). In human reticulocytes (unlike those from rabbits), addition of ferric salicylaldehyde isonicotinoylhydrazone, to increase the pre-heme iron pool independently of the transferrin cycle, failed to promote heme synthesis or modify feedback inhibition induced by hematin. In human erythroid cells (but not rabbit reticulocytes) pre-incubation with unlabeled delta-aminolevulinate or protoporphyrin IX greatly stimulated utilization of cell 59Fe for heme synthesis and also attenuated end product inhibition. In human erythroid cells heme biosynthesis is thus primarily regulated by feedback inhibition at one or more steps which lead to delta-aminolevulinate formation. Hence in man the regulatory process affects generation of the first committed precursor of porphyrin biosynthesis by delta-aminolevulinate synthetase, whereas in the rabbit separate regulatory mechanisms exist which control the incorporation of iron into protoporphyrin IX.     

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.     

Purification, crystallization and preliminary analysis of hemoglobin from rabbit (Oryctolagus cuniculus)

Hemoglobin (Hb) is a tetrameric protein, which contains four heme prosthetic groups, and each one is associated with a polypeptide chain. Herein, we report the rabbit hemoglobin which has intrinsically high oxygen affinity and possess highest sequence identity with human hemoglobin. The purified hemoglobin has been tried to crystallize in different crystallization conditions owing to its formation of various crystal systems. The rabbit Hb crystals were grown using PEG 3,350 as the precipitant at 18 degrees C. The crystals of rabbit Hb belongs to triclinic space group P1 with one molecule (alpha2beta2) in the asymmetric unit.     

Heme deficiency in erythroid lineage causes differentiation arrest and cytoplasmic iron overload

Erythroid 5-aminolevulinate synthase (ALAS-E) catalyzes the first step of heme biosynthesis in erythroid cells. Mutation of human ALAS-E causes the disorder X-linked sideroblastic anemia. To examine the roles of heme during hematopoiesis, we disrupted the mouse ALAS-E gene. ALAS-E-null embryos showed no hemoglobinized cells and died by embryonic day 11.5, indicating that ALAS-E is the principal isozyme contributing to erythroid heme biosynthesis. In the ALAS-E-null mutant embryos, erythroid differentiation was arrested, and an abnormal hematopoietic cell fraction emerged that accumulated a large amount of iron diffusely in the cytoplasm. In contrast, we found typical ring sideroblasts that accumulated iron mostly in mitochondria in adult mice chimeric for ALAS-E-null mutant cells, indicating that the mode of iron accumulation caused by the lack of ALAS-E is different in primitive and definitive erythroid cells. These results demonstrate that ALAS-E, and hence heme supply, is necessary for differentiation and iron metabolism of erythroid cells.     

Heme biosynthesis in a chicken hepatoma cell line (LMH): comparison with primary chick embryo liver cells (CELC)

5-Aminolevulinic acid synthase (ALA synthase), the rate-controlling enzyme of hepatic heme biosynthesis, is feed-back repressed by heme. In the liver, chemicals such as barbiturates markedly induce ALA synthase, especially in the presence of partial defects of heme biosynthesis. The inducibility and regulation of ALA synthase have been investigated using a variety of models, including intact animals and liver cell culture systems. A widely used model that closely approximates what occurs in vivo and in humans is that of primary cultures of chick embryo liver cells (CELCs). However, CELCs have some limitations: the cells obtained are somewhat heterogeneous; isolation and culture must be repeated every week resulting in weekly variations; and cells are short-lived limiting the feasibility of time-course and transfection studies. The aim of this study was to determine if LMH cells, a chick hepatoma cell line, are a good model comparable to that of CELCs. In both cells similar patterns of response of, ALA synthase activities and mRNA levels, and of porphyrin accumulation were obtained following treatments known to affect heme biosynthesis. Similarly, heme repressed ALA synthase mRNA levels in both cell types and ALA synthase activities in LMH cells. We conclude that LMH cells are a useful model for the study of hepatic heme biosynthesis and regulation of ALA synthase.     

Biosynthesis of rainbow trout (Salmo gairdnerii) hemoglobins in vitro

Cell free systems were established to analyze the biosynthesis of trout hemoglobins I, II and III. HbI, II and III were synthesized in trout erythroid cell lysates as well as in a mRNA dependent rabbit reticulocyte lysate supplemented with trout erythroid cell polyA-RNA. The newly synthesized hemoglobins apparently contained the N alpha-acetyl modification at their alpha-chain amino terminals since they co-migrated with carrier trout hemoglobins that are known to contain the modification. This observation suggests that the acetylation is determined by the information encoded in the mRNA.     

Haemoglobin biosynthesis site in rabbit embryo erythroid cells

Properly metabolized globin synthesis and iron uptake are indispensable for erythroid cell differentiation and maturation. Mitochondrial participation is crucial in the process of haeme synthesis for cytochromes and haemoglobin. We studied the final biosynthesis site of haemoglobin using an ultrastructural approach, with erythroid cells obtained from rabbit embryos, in order to compare these results with those of animals treated with saponine or phenylhydrazine. Our results are similar to those obtained in assays with adult mammals, birds, amphibians, reptiles and fish, after induction of haemolytic anaemia. Therefore, the treatment did not interfere with the process studied, confirming our previous findings. Immunoelectron microscopy showed no labelling of mitochondria or other cellular organelles supposedly involved in the final biosynthesis of haemoglobin molecules, suggesting instead that it occurs free in the cytoplasm immediately after the liberation of haeme from the mitochondria, by electrostatic attraction between haeme and globin chains.     

Expression of coproporphyrinogen oxidase and synthesis of hemoglobin in human erythroleukemia K562 cells.

Coproporphyrinogen oxidase (CPOX), the sixth enzyme in the heme-biosynthetic pathway, catalyzes oxidative decarboxylation of coproporphyrinogen to protoporphyrinogen and is located in the intermembrane space of mitochondria. To clarify the importance of CPOX in the regulation of heme biosynthesis in erythroid cells, we established human erythroleukemia K562 cells stably expressing mouse CPOX. The CPOX cDNA-transfected cells had sevenfold higher CPOX activity than cells transfected with vector only. Expression of ferrochelatase and heme content in the transfected cells increased slightly compared with the control. When K562 cells overexpressing CPOX were treated with delta-aminolevulinic acid (ALA), most became benzidine-positive without induction of the expression of CPOX or ferrochelatase, and the heme content was about twofold higher than that in ALA-treated control cells. Increases in cellular heme concomitant with a marked induction of the expression of heme-biosynthetic enzymes, including CPOX, ferrochelatase and erythroid-specific delta-aminolevulinic acid synthase, as well as of alpha-globin synthesis, were observed when cells were treated with transforming growth factor (TGF)beta 1. These increases in the transfected cells were twice those in control cells, indicating that overexpression of CPOX enhanced induction of the differentiation of K562 cells mediated by TGF beta 1 or ALA. Conversely, the transfection of antisense oligonucleotide to human CPOX mRNA into untreated and TGF beta 1-treated K562 cells led to a decrease in heme production compared with sense oligonucleotide-transfected cells. These results suggest that CPOX plays an important role in the regulation of heme biosynthesis during erythroid differentiation.     

Control of hemoglobin synthesis in erythroid differentiating K562 cells: II. Studies of iron mobilization in erythroid cells by high-performance liquid chromatography–electrochemical detection

We have demonstrated that iron controls hemoglobin (Hb) synthesis in erythroid differentiating K562 cells by enhancing the activity of a key enzyme of the Hb synthesis, δ-aminolevulinate synthase (ALAS). In the present study, we studied iron mobilization and the role of iron in erythroid differentiating cells by measuring the level of iron by means of high-performance liquid chromatography using electrochemical detection (HPLC–ED). After treatment of K562 cells with sodium butyrate, the expression of transferrin receptor (TfR) increased initially, followed by an increase in the levels of both total iron and Hb as well as the ALAS activity. However, no increase could be found in the levels of non-heme iron, low-molecular-mass iron (LMMFe) and ferritin. Addition of diferric transferrin (FeTf) enhanced both δ-aminolevulinic acid (ALA) and Hb synthesis. In contrast, addition of hemin elevated the levels of all iron species as well as the Hb synthesis but reduced the TfR expression and ALA contents in both butyrate treated and untreated cells. These results suggest that Hb synthesis is controlled by TfR expression, and that the ALA synthesis is suppressed by iron released from heme and/or Hb due to lowered expression of TfR.     

Inhibitor of heme synthesis in polycythemic rabbit serum

Sera from hypertransfused polycythemic rabbits were found to significantly inhibit ⁵⁹Fe incorporation into heme in erythroid cells in normal rabbit bone marrow cultures when compared with that of normal serum controls suggesting a higher concentration of this inhibitor in polycythemic serum. This serum inhibitor delayed the time of peak cumulative heme synthesis $\text{in}$$\text{vitro}$ and the delay in peak cumulative heme synthesis was increase with increasing concentrations of polycythemic serum. It is suggested from these studies that this serum inhibitor may be involved in a negative feedback system in the control of erythropoiesis and may act specifically on differentiated nucleated erythroid cells to delay their entry into the cell cycle, consequently inhibiting heme synthesis.     

Non-transferrin donors of iron for heme synthesis in immature erythroid cells

The mechanism of iron uptake from several iron-containing compounds by transferrin-depleted rabbit reticulocytes and mouse spleen erythroid cells was investigated. Iron complexes of DL-penicillamine, citrate and six different aroyl hydrazones may be utilized by immature erythroid cells for hemoglobin synthesis, although less efficiently than iron from transferrin. HTF-14, a monoclonal antibody against human transferrin, reacts with rabbit transferrin and inhibits iron uptake and heme synthesis by rabbit reticulocytes. HTF-14 had no significant effect on iron uptake and heme synthesis when non-transferrin donors of iron were examined. Ammonium chloride (NH4Cl) increases intracellular pH and blocks the release or utilization of iron from the internalized transferrin. NH4Cl only slightly affected iron incorporation and heme synthesis from non-transferrin donors of iron. Hemin inhibited transferrin iron uptake and heme synthesis, but had a much lesser effect on iron incorporation and heme synthesis from non-transferrin donors of iron. These results allow us to conclude that transferrin-depleted reticulocytes take up iron from all of the examined non-transferrin iron donors without the involvement of the transferrin/transferrin receptor pathway.     

Erythroid expression of the heme-regulated eIF-2 alpha kinase.

The role of heme-regulated eIF-2 alpha kinase (HRI) in the regulation of protein synthesis in rabbit reticulocytes is well documented. Inhibitors of protein synthesis with properties similar to those of HRI have been described in some nonerythroid cell types, but it has not yet been determined whether these eIF-2 alpha kinase activities are mediated by HRI or one or more as yet uncharacterized kinases. We have studied the expression of mRNA, polypeptide, and kinase activities of HRI in various tissues from both nonanemic and anemic rabbits. Our results indicate that HRI is expressed in an erythroid cell-specific manner. HRI is present in the bone marrow and peripheral blood of both nonanemic and anemic rabbits but not in any of the other tissues tested. HRI mRNA is present at low levels in uninduced mouse erythroleukemic (MEL) cells and human K562 cells and accumulates to higher levels upon induction. The accumulation of HRI mRNA in differentiating MEL cells is dependent upon the presence of heme. The addition of 3-amino-1,2,4-triazole (AT), an inhibitor of heme biosynthesis, to the induction medium markedly reduced HRI mRNA accumulation. Simultaneous addition of hemin and AT to the dimethyl sulfoxide induction medium largely prevented the inhibition of HRI mRNA induction by AT. These findings indicate that HRI is expressed in an erythroid cell-specific manner and that the major physiologic role of HRI is in adjusting the synthesis of globins to the availability of heme.