The effect of transferrin saturation on internal iron exchange

Radioiron was introduced into the intestinal lumen to evaluate absorption, injected as nonviable red cells to evaluate reticuloendothelial (RE) processing of iron, and injected as hemoglobin to evaluate hepatocyte iron processing. Redistribution of iron through the plasma was evaluated in control animals and animals whose transferrin was saturated by iron infusion. Radioiron introduced into the lumen of the gut as ferrous sulfate and as transferrin-bound iron was absorbed about half as well in iron-infused animals, and absorbed iron was localized in the liver. The similar absorption of transferrin-bound iron suggested that absorption of ferrous iron occurred via the mucosal cell and did not enter by diffusion. The decrease in absorption was associated with an increase in mucosal iron and ferritin content produced by the iron infusion. An inverse relationship (r = -0.895) was shown between mucosal ferritin iron and absorption. When iron was injected as nonviable red cells, it was deposited predominantly in reticuloendothelial cells of the spleen. Return of this radioiron to the plasma was only 6% of that in control animals. While there was some movement of iron from spleen to liver, this could be accounted for by intravascular hemolysis. Injected hemoglobin tagged with radioiron was for the most part taken up and held by the liver. Some 13% initially localized in the marrow in iron-infused animals was shown to be storage iron unavailable for hemoglobin synthesis. These studies demonstrate the hepatic trapping of absorbed iron and the inability of either RE cell or hepatocyte to release iron in the transferrin-saturated animal.     

A1 and A2 adenosine receptor regulation of erythropoietin production

The effects of adenosine (ADE) and ADE agonists on erythropoietin (Ep) production were determined using percent (%) 59Fe incorporation in red cells of exhypoxic polycythemic mice. The hemisulfate salt of ADE produced a significant increase in % 59Fe incorporation in response to hypoxia in concentrations of 400 to 1600 nmol/kg/day (i.v.). 5'-N-ethyl-carboxamideadenosine (NECA), a selective A2 receptor agonist, increased radioiron incorporation in a dose-dependent manner (10-100 nmol/kg/day, i.v.). In contrast, N6-cyclohexyladenosine (CHA), a selective A1 receptor agonist, did not affect radioiron incorporation in concentrations up to 1600 nmol/kg/day (i.v.). Albuterol, a beta 2-adrenergic agonist, enhanced % 59Fe incorporation in polycythemic mice and low doses of CHA (50 and 100 nmol/kg/day), which were not effective alone on % 59Fe incorporation in polycythemic mice exposed to hypoxia, inhibited the enhancement in radioiron induced by albuterol (25 and 100 micrograms/kg/day, i.p.) plus hypoxia. Theophylline (20 and 80 mg/kg/day, i.p.), a well-known antagonist of ADE receptors, blocked the ADE and NECA enhancement in radioiron incorporation at a dose of theophylline alone which produced only a slight enhancement of % 59Fe incorporation. These results suggest that ADE may both inhibit through A1 receptor activation and increase via A2 receptor stimulation the production of Ep.     

An analytical study of in vivo survival of limited populations of animal red blood cells tagged with radio-iron

Animal red blood cell in vivo survival curves, obtained by the radioiron tagging of populations of approximately the same age followed by the administration of non-radioactive iron to suppress radioiron reutilization, have been subjected to mathematical analysis on the basis of the three following assumptions:— (A) Red blood cells disappear from the circulation as the result of senescence: there is an average life span around which the life spans of individual cells are distributed in the usual way. (B) Red blood cells may be removed from the circulation by a process of random destruction which continuously removes a constant fraction of the cells present at any moment irrespective of age or other characteristics. (C) Under the conditions of the experiments described, a fraction of the radioiron, constant for each animal, is reutilized in new red cell formation when released by red cell destruction. This mathematical analysis indicates the following average life spans with the respective standard errors of the mean: dog 107 days ± 1.14; rabbit 67.6 days ± 1.94; cat 68.4 ± 1.50. The mathematical treatment presented has permitted a consideration of the theoretical variation of red cell life spans which was found in these experiments to be relatively small for all three species studied. In the rabbit and cat 2.5 per cent of tagged populations of red cells of the same age would theoretically have disappeared by senescence 17 days before the average life span was reached. The variation of red cell life in the dog was slightly less. Animals of the three species studied, in spite of apparently normal health, exhibited varying degrees of random destruction of both autogenous and transfused fresh normal homologous red cells. As yet, we have no explanation for this random loss of cells occurring in apparently healthy normal animals. The method of mathematical analysis presented is applicable to animal red cell survival studies employing radioiron in which differing rates of random destruction are operating in the removal of red cells.     

Heme and non-heme iron transporters in non-polarized and polarized cells

Background  

Heme and non-heme iron from diet, and recycled iron from hemoglobin are important products of the synthesis of iron-containing molecules. In excess, iron is potentially toxic because it can produce reactive oxygen species through the Fenton reaction. Humans can absorb, transport, store, and recycle iron without an excretory system to remove excess iron. Two candidate heme transporters and two iron transporters have been reported thus far. Heme incorporated into cells is degraded by heme oxygenases (HOs), and the iron product is reutilized by the body. To specify the processes of heme uptake and degradation, and the reutilization of iron, we determined the subcellular localizations of these transporters and HOs.     

REUTILIZATION OF LYMPHOCYTE DNA BY CELLS OF INTESTINAL CRYPTS AND REGENERATING LIVER

Lymphoid cells from mice injected 54 hours and 30 hours earlier with ³H-thymidine were washed and transfused into isogenic recipients at 29 to 30 hours after partial hepatectomy. The recipients were killed 28 to 30 hours later, and liver, intestine, Peyer''s patch, spleen, and the transfused cells were examined in autoradiographs exposed 6 months. Approximately 80 per cent of the labeled transfused cells were classed as lymphocytes. The labeled DNA contained in the transfused cells was partitioned to about 14 times as many recipient liver and intestinal cells, appearing in 72 to 78 per cent of hepatocyte nuclei, in 30 to 35 per cent of liver reticuloendothelial nuclei, and in 90 to 95 per cent of intestinal crypt nuclei. The label was not comparably widespread in the lymphoid organs, but was limited to a few intensely labeled lymphocytes and a somewhat larger number of very weakly labeled cells. When heat-killed cells rather than living cells were transfused, intensely labeled lymphocytes were absent from the lymphoid organs, but the labeling of cells in the recipients was otherwise identical. The results suggest that (a) reutilized DNA is derived from dead cells, (b) reutilized DNA is mainly degraded to nucleosides and nucleotides, the usual immediate de novo DNA precursors, before reincorporation into DNA, and (c) DNA reutilization may occur in the lymphoid organs, but on a less active scale than in intestine or regenerating liver.     

The induction of ferritin synthesis in circulating larval red blood cells.

The circulating red blood cells formed in bullfrog larvae, chicken embryos, and mouse embryos contain large amounts of ferritin and storage iron in excess of the need for hemoglobin. In contrast, the circulating red cells of adult animals contain little ferritin. Ferritin synthesis and iron storage are coordinated with differentiation and hemoglobin synthesis in the red cells of adults. In order to test the hypothesis that ferritin synthesis could be controlled independently of hemoglobin synthesis and differentiation in the red cells formed early in life, bullfrog larvae were injected with iron to determine if ferritin synthesis was increased in the circulating red cells. Within 17 h after the injection of iron, the synthesis of ferritin, assayed as the incorporation of [14C]leucine by cell suspensions prepared from circulating red cells, was increased from 2.9 to 10.2% of the total protein, and the specific activity of the ferritin synthesized increased from 1100 to 3000 cpm/A280. There was no change in the hematocrit of the animals nor in the specific activity of hemoglobin synthesized by suspensions of red cells (average, 720 cpm/A280). The results suggest that in mature, larval red cells, ferritin synthesis can be controlled by changes in the extracellular environment. The results also indicate that ferritin synthesis can be controlled independently of hemoglobin synthesis with which it is coordinated during erythroid differentiation in adult animals.     

Nerve Regeneration and Cholesterol Reutilization Occur in the Absence of Apolipoproteins E and A-I in Mice

Abstract: Apolipoproteins have been implicated in the salvage and reutilization of myelin cholesterol during Wallerian degeneration and the subsequent nerve regeneration. Current evidence suggests that myelin cholesterol complexes with apolipoproteins E and A-I to form lipoproteins that are taken up via low-density lipoprotein receptors on myelinating Schwann cells. We recently reported, however, that apolipoprotein E is not required for nerve regeneration or reutilization of myelin cholesterol. We have now investigated nerve regeneration and the reutilization of cholesterol in mutant mice deficient in both apolipoproteins E and A-I. Morphologic examination of nerves 4 and 12 weeks after crush injury revealed that regeneration proceeded at a normal rate in the absence of these apolipoproteins. Autoradiography of regenerating nerves indicated that prelabeled myelin lipid was reutilized in the regenerating myelin. 3-Hydroxy-3-methylglutaryl-CoA reductase, the rate-limiting enzyme in cholesterol synthesis, was down-regulated in the regenerating nerves, indicative of cholesterol uptake via lipoproteins. Prelabeled myelin cholesterol was present in lipoprotein fractions isolated from crushed nerves of mutant mice. These data suggest that there is considerable redundancy in the process of cholesterol reutilization within nerve, and that apolipoproteins other than apolipoproteins E and A-I may be involved in the recycling of myelin cholesterol.     

Cooperative erythropoietic assay of several steroid metabolites in polycythemic mice

A blinded cooperative assay of several androstane and pregnane steroid metabolites has been carried out in order to determine whether 5β-H derivatives are as active as testosterone in stimulating in vivo erythropoiesis. The steroids tested were: testosterone, 5-dihvdrotestosterone, 5β-dihydrotestosterone, 5β-pregnane-3,20-dione, 3-dihydroxy-5β-pregnàne-11,20-dione and 3β-hydroxy-5β-pregnan-20-one. The incorporation of radioactive iron into newly formed red cells in exhypoxic polycythemic mice was used to compare the effects of the steroids. Testosterone and 5-dihydrotestosterone both produced significant increases in ⁵⁹Fe incorporation. 5β-dihydrotestosterone, 5β-pregnane-3,20-dione, 3-hydroxy-5β-pregnane-11,20-dione and 3β-hydroxy-5β-pregnan-20-one were all devoid of significant erythropoietic activity in polycythemic mice in almost all instances. Thus, under the conditions chosen, this study failed to demonstrate that 5β-steroids increase radioactive iron incorporation in red cells of exhypoxic polycythemic mice.     

Iron metabolism and erythropoiesis in the prenatal and early postnatal periods of the rat

Spectrophotometric studies have been made on iron balance in the liver, spleen, bone marrow, and blood serum of 15-, 17- and 20-day rat embryos, as well as 1-90 days old rats. It was shown that foetal period is the main one for the formation of iron-accumulating function of the liver. Anaemic period in 14-28-day rat puppies results from insufficient hemoglobin synthesis, rather than from iron deficiency in the organism. The latter is observed in 35-60-days old rats. Maturation of the spleen as the organ involved in reutilization of iron was noted in 42-60-day rats.     

Vitellogenin-iron and hemoglobin synthesis in avian reticulocytes

Avian vitellogenin has been studied as an iron carrier for hemoglobin synthesis by reticulocytes. The Fe-vitellogenin uptake by the immature red cells is progressive with time, following an unspecific iron uptake process. The iron uptake from Fe-vitellogenin was in proportion to the immature red cells present and the radioactive iron was found in the hemoglobin synthesized by these cells. These results open up the possibility of assigning a secondary role to the Fe-vitellogenin in the avian erythropoiesis, added to the classical iron transport function for egg production.     

A mathematical model of iron metabolism

A mathematical model of iron metabolism is presented. It comprises the following iron pools within the body: transferrin-bound iron in the plasma, iron in circulating red cells and their bone marrow precursors, iron in mucosal, parenchymal and reticuloendothelial cells. The control exerted by a hormone, called erythropoietin, on bone marrow utilization of iron for hemoglobin synthesis is taken into account. The model so obtained consists of a system of functional differential equations of retarded type. Most model parameters can be estimated from radiotracer experiments, others can be measured and numerical values can be assigned to the remaining ones making few reasonable assumptions according to the available physiological knowledge. Iron metabolism behavior under different therapeutical treatments was simulated. Model predictions were compared to experimental data collected in clinical routine.This work has been partially supported by C.N.R. (Italy) through grants N. 80.01227.07 and N. 81.00888.07     

Rate of microsomal protein metabolism in the mouse liver

NaH14CO3, a poorly reutilized biosynthesis precursor, was used to study the rate of whole microsomal protein degradation in mouse liver. The use of the precursors, however, does not prevent the reutilization of labeled amino acids on phenobarbital administration. To avoid reutilization, a new method has been developed. It was shown that phenobarbital injections have no effect on the degradation rate of the whole microsomal protein. The effect of amidopyrine, a monooxygenase microsomal system substrate, on the rate of whole microsomal protein degradation was examined. An experimental model was developed, in which the monooxygenase microsomal system substrate does not exhibit the properties of its inducer. Amidopyrine administration to mice simultaneously with phenobarbital induction has no effect on the degradation rate of the whole microsomal protein.     

Hemoglobin and heme scavenging

Release of hemoglobin into plasma is a physiological phenomenon associated with intravascular hemolysis. In plasma, stable haptoglobin-hemoglobin complexes are formed and these are subsequently delivered to the reticulo-endothelial system by CD163 receptor-mediated endocytosis. Heme arising from the degradation of hemoglobin, myoglobin, and of enzymes with heme prosthetic groups could be delivered in plasma. Albumin, haptoglobin, hemopexin, and high and low density lipoproteins cooperate to trap the plasma heme, thereby ensuring its complete clearance. Then hemopexin releases the heme into hepatic parenchymal cells only after internalization of the hemopexin-heme complex by CD91 receptor-mediated endocytosis. Moreover, alpha1-microglobulin contributes to heme degradation by a still unknown mechanism, with the concomitant formation of heterogeneous yellow-brown kynurenine-derived chromophores which are very tightly bound to amino acid residues close to the rim of the lipocalin pocket. During hemoglobin synthesis, the erythroid alpha-chain hemoglobin-stabilizing protein specifically binds free alpha-hemoglobin subunits limiting the free protein toxicity. Although highly toxic because capable of catalyzing free radical formation, heme is also a major and readily available source of iron for pathogenic organisms. Gram-negative bacteria pick up the heme-bound iron through the secretion of a hemophore that takes up either free heme or heme bound to heme-proteins and transports it to a specific receptor, which, in turn, releases the heme and hence iron into the bacterium. Here, hemoglobin and heme trapping mechanisms are summarized.     

Electrophoresis of phosphoglycerate kinase

A technique for the visualization of phosphoglycerate kinase on starch gel after electrophoresis is described. Three bands of activity were found in hemolysates prepared from normal red cells. When ATP, a substrate of the enzyme, was incorporated into the gel, only a single band was found. This suggested that ATP complexed with the enzyme and/or produced configurational changes. Incidentally, it was found that ATP markedly altered the electrophoretic mobility of hemoglobin. Red cells of 92 Caucasian males, 121 Caucasian females, 114 Negro males, 10 Negro females, 4 Oriental males, and 4 Oriental females were examined. No evidence of an electrophoretic polymorphism of this enzyme was found. Patterns of activity similar to those found in red cells were found in liver, heart, kidney, and skeletal muscle.This work was supported, in part, by Public Health Service Grant No. 07449 from the National Heart Institute, NIH. Presented, in part, at the annual meeting of the American Society of Human Genetics, Austin, Texas, October 12, 1968.     

高原低氧胁迫对小鼠肝脏功能及基因表达的影响

低氧作为青藏高原最为特殊的环境因素之一,对高原动物的适应进化产生了深刻的影响。持续的低氧暴露会损伤肝脏功能,引起动物机体代谢紊乱,但连续低氧处理对子代肝脏的影响仍缺乏相关研究。本研究将成年小鼠转移至高原低氧环境(海拔3 220 m)饲养并繁殖,以常氧条件下饲养小鼠为对照,统计低氧处理小鼠(低氧第0代)及其子代(低氧第1～5代)生长数据,发现长期低氧暴露导致小鼠肝脏比重增加,肝细胞肿胀,肝索间红细胞浸润,并且子一代小鼠肝小叶出现脂肪变性。血液生化指标显示,相比于对照组(常氧第0代),低氧第0代和低氧第1代的谷丙转氨酶和谷草转氨酶水平显著上升(P <0.05);血清白蛋白、球蛋白、总胆红素和总胆固醇水平在低氧第0代中下降,低氧第1代中上升(P <0.05)。空腹注射葡萄糖和胰岛素后低氧组小鼠的葡萄糖耐受能力和胰岛素敏感性显著减弱(P <0.05)。常氧第0代、低氧第0代及低氧第1代肝脏RNA-seq分析发现,低氧第0代和低氧第1代共有的459个差异基因显著富集在MAPK、细胞凋亡、脂质代谢和内质网等信号通路。本研究发现低氧胁迫对子代小鼠肝脏具有重要影响,此结果对肝脏低氧生...     

Changes in transferrin during the red cell replacement in amphibia

Transferrin, a plasma glycoprotein, carries iron from storage sites to immature erythroid cells for hemoglobin synthesis. The replacement of larval red cells by adult red cells, which occurs during metamorphosis in bullfrogs, requires extensive formation of hemoglobin and new red cells. Large changes in red cell iron storage also occur during the red cell replacement. Both the concentration and the level of iron saturation of plasma transferrin were measured during metamorphosis to determine if there were changes in plasma transferrin which coincided with the changes in red cell iron storage and ferritin content. Plasma transferrin concentrations increased from 0.96 to 2.6 mg/ml during the period when red cell storage iron and ferritin decreased. Plasma iron concentrations also increased when the transferrin concentration increased, suggesting that the additional transferrin may be involved in moving iron from the larval red cell stores. At the end of metamorphosis, the plasma iron concentration decreased to premetamorphic levels but the transferrin concentration remained high, resulting in a decrease in saturation to 18% compared to 45% in the larvae. In addition to differences in iron saturation, adult transferrin had different electrophoretic properties from larval transferrin. The results support the hypotheses that during early ontogeny plasma transferrin and red cell iron storage are coordinated to provide iron for the formation of the first generation of adult red cells and that transferrin may participate in the control of red cell ferritin synthesis.     

Erythropoietin titers in response to anemia or hypoxia

The normal response to anemic or hypoxic hypoxia is synthesis and release of erythropoietin in accord with the concept that erythropoietin production is controlled by a renal oxygen sensor. In this study, erythropoietin production, as predicted, was abrogated in patients with renal impairment (55 cases), but normal in nonuremic individuals. Specifically, patients with rheumatoid arthritis (34 cases), sickle cell anemia (25 cases), aregenerative anemia (27 cases), and aplastic anemia (13 cases) had erythropoietin titers overlapping with those observed in simple anemia (61 cases) at corresponding hematocrits. The response of polycythemic laboratory animals to hypoxia is more difficult to fit within the concept of an oxygen sensor responsive both to anemic and hypoxic hypoxia. If the polycythemia was induced by hypertransfusion, erythropoietin production in response to hypoxia was, as predicted, less than that observed in normal animals. If, however the polycythemia was induced by previous exposure to hypoxia, the animals responded to hypoxia as though they were not polycythemic. An explanation for this challenging observation may provide a clue as to the operation of the oxygen sensor.     

INTRANUCLEAR AGGREGATES OF FERRITIN IN LIVER CELLS OF MICE TREATED WITH SACCHARATED IRON OXIDE : Their Possible Relation to Nuclear Protein Synthesis

Several months following parenteral injections of saccharated iron oxide into DBA/2J mice, granules rich in iron were found in nuclei of scattered parenchymal liver cells as well as in the cytoplasm. As seen in the light microscope, the intranuclear granules were brown; most of them measured between 0.5 µ and 1 µ in cross-section. They gave positive Prussian blue tests, and were not selectively stainable with pyronine. Electron micrographs of the granules showed closely packed aggregates of ferritin molecules, occasionally in paracrystalline order. The intranuclear collections were often surrounded by bands of material of moderate opacity. Scattered ferritin molecules and collections of such molecules were also present in the cytoplasm of many liver cells, but there seemed to be no quantitative relationship between intranuclear and cytoplasmic ferritin. Liver cells from untreated control mice failed to reveal intranuclear deposits of ferritin. Although the site of origin of the intranuclear aggregates of ferritin is unknown, the findings suggest the possibility that under suitable circumstances ferritin synthesis may take place within nuclei of liver cells—perhaps induced by the presence of colloidal iron.     

Developmental plasticity in aerobic performance in deer mice (Peromyscus maniculatus)

While several studies have examined the abiotic effects of altitude (low ambient temperatures and hypoxia) on the aerobic performance of small mammals, few have explored the effects of development and maturation at different altitudes on aerobic performance as adults. We examined the basal metabolism and aerobic performance of deer mice (Peromyscus maniculatus) under four different developmental and testing regimes: (1) reared (gestation through weaning) and tested at high altitude; (2) reared and tested at low altitude; (3) reared at low altitude and tested at high altitude after acclimation; and (4) reared at low altitude and tested in hypoxia without acclimation. We found that mice that developed and were tested at low altitudes had a higher aerobic capacity (both aerobic performance and basal metabolic rate) than those that developed, or were acclimated as adults, at high altitudes. In addition, we found that mice that developed at high altitude did not have a higher aerobic capacity than those that developed at low altitude and were acclimated to high altitude as adults. Both groups tested at high altitudes had higher hematocrits (% red blood cells) and hemoglobin than mice tested at low altitudes. Surprisingly, mice acclimated to low altitudes and given an instantaneous exposure to hypoxia did not suffer a depression in aerobic performance.