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.     

Exceptional iron concentrations in larval lampreys (Geotria australis) and the activities of superoxide radical detoxifying enzymes.

This study aimed to elucidate the way in which larvae of the lamprey Geotria australis counteract the potential problems of the very high concentrations of non-haem iron they contain and thereby avoid the deleterious effects associated with iron overload in other vertebrates. Particular attention has been paid to ascertaining whether increasing concentrations of iron are accompanied by (i) change to a less readily available form of iron and (ii) an increase in the activity of those detoxifying enzymes responsible for minimizing the production of harmful hydroxyl radicals via the Haber-Weiss reaction. The mean concentrations of haemosiderin and ferritin in larval G. australis were each far higher in the nephric fold than in either the liver or intestine, but all these concentrations were much greater than those in rat liver. Since haemosiderin releases iron far more slowly than ferritin, the iron it contains is much less readily available to catalyse the Haber-Weiss reaction. It is thus relevant that (i) non-haem iron in the nephric fold occurred to a greater extent as large dense haemosiderin granules than as ferritin molecules and (ii) the proportion of iron in the form of haemosiderin rose with increasing concentration of total non-haem iron. A strong correlation was also recorded between the activity of superoxide dismutase in the nephric fold and the concentrations of total non-haem iron and its haemosiderin and ferritin components. This demonstrates that enzyme detoxification of O2.- rises with increasing amounts of iron. The exceptional iron concentrations in the nephric fold were not reflected by a greater measured activity of superoxide dismutase than that found in other tissues. However, the nephric fold was shown to contain an augmentation factor which is presumed to enhance the activity of this enzyme in vivo. The activity of catalase and glutathione peroxidase, which catalyse the breakdown of H2O2 to O2 and water, were each significantly correlated with the concentration of ferritin.     

Depot iron in the rat liver after hypertransfusion with rat erythrocytes

In the rat liver the deposition of iron was measured after hypertransfusion with rat erythrocytes. The liver iron fractions were studied during four weeks after the hypertransfusions. In the first week the haemosiderin iron fraction increased together with the ferritin iron fraction. Most iron was deposited as ferritin iron. In the last week of the experiments, while the ferritin iron fraction still increased, the haemosiderin iron fraction decreased. At the same time plasma iron was utilized when erythropoiesis, which had been suppressed by the hypertransfusion, recommenced. It is suggest that, under these experimental conditions, liver haemosiderin iron is used in haemoglobin synthesis.     

Quantification of iron deposits in several body tissues of lampreys (Petromyzon marinus L.) throughout the life cycle

• 1.1. Inductively coupled plasma atomic emission spectroscopy (ICP-AES) was used to measure iron concentration in several body tissues throughout the life cycle of the lamprey, Petromyzon marinus L.
• 2.2. Iron concentration in the liver rises sharply during metamorphosis, decreases in parasitic adults, and falls to the lowest value in upstream migrants.
• 3.3. In the intestine, the concentration of this metal is highest in the larval stage, but values decline steadily through transformation to their lowest levels in parasitic adults.
• 4.4. Dorsal skin has, on average, three times the iron content of ventral skin and it is only in upstream migrants that the levels of both regions increase significantly over those of other stages.
• 5.5. Differences in iron concentration in tissues of larval and adult lampreys reflect changes which take place at metamorphosis.

     

The relationship between total non-haem,ferritin and haemosiderin iron in larvae of Southern Hemisphere lampreys (Geotria australis andMordacia mordax)

Summary The major iron binding protein (IBP) of larvalM. mordax has an estimated molecular weight (354,000), subunit molecular weight (18,000) and pI (5.1) identical to those recorded previously for larvalG. australis. The IBP in larvalG. australis has also been shown to be relatively heat stable and to react immunologically with antihorse spleen ferritin. The weight of total non-haem iron in the whole body, and both the ferritin and haemosiderin iron components, increased with increasing body weight in larvalG. australis. While the concentration of ferritin iron remained similar throughout larval life, the concentration of total non-haem iron and haemosiderin iron increased rapidly in animals up to a body weight of 0.1–0.2 g, but thereafter rose only slowly throughout the rest of larval life. This implies that any iron in excess of the amount required for the maintenance of a constant ferritin concentration is converted into haemosiderin iron, and that once non-haem iron has reached a particular concentration (c. 500–600 g g^–1), the rate of iron accumulation is greatly reduced. While the larvae of bothG. australis andM. mordax had very high plasma iron levels (>19,000 g 100 ml^–1), the former had significantly greater concentrations of iron in the whole body (702vs. 267 g g^–1) and more particularly in the nephric fold (7382vs. 224 g g^–1). A greater reservoir of non-haem iron could facilitate the maintenance of the large amounts of haem and erythrocytic ferritin present in this species as a result of an exceptionally high haemoglobin concentration and red blood cell number. The greater concentration of non-haem iron in the intestine ofM. mordax than ofG. australis (1338vs. 824 g g^–1), when considered in conjunction with histological studies, indicates thatMordacia mordax eliminates a larger amount of iron during the extrusion of its intestinal columnar cells.Abbreviation IBP iron binding protein     

Prenatal and postnatal changes in the content and species of ferritin in rat liver

The iron and ferritin content of rat liver and the species of ferritin present were examined from 4 days before to 3 weeks after birth. 1. Total iron and ferritin iron accumulated rapidly during the last days of gestation and from the second postnatal day underwent a steady depletion. 2. The amount of iron deposited before birth in the liver of each pup varied inversely with litter size and could be increased moderately by injection of iron into the mother before mating. 3. Intraperitoneal injection of iron 1 day after birth doubled the concentration of total iron, ferritin iron and ferritin protein in the liver over the next 24h, but at 3 weeks after birth it raised the very low concentrations of iron and ferritin severalfold. 4. As shown by electrophoretic migration, ferritin and dissociated ferritin subunits prepared from the livers of rats from 4 days before to 3 weeks after birth differed from those of adult liver ferritin and were indistinguishable from those of adult kidney and spleen ferritin. Treatment with iron at 3 weeks of age induced formation of a ferritin with electrophoretic properties resembling those of adult liver. It is concluded that iron given at this stage of development may activate the genetic cistron for adult liver ferritin.     

Ferritin in liver, plasma and bile of the iron-loaded rat

Rats were loaded with iron. With overload, up to a 10-fold increase of the iron and ferritin protein content of the livers was measured. The plasma ferritin concentration increased gradually with the ferritin concentration in the liver. The ferritin concentration in the bile increased also and was in the same range as in the plasma. The ratio plasma ferritin concentration to bile ferritin concentration in individual rats decreased in the case of considerable iron overload. After intravenous injection of liver ferritin, less than 2% of the ferritin concentration that disappeared from the blood was found to be in the bile. Isoelectric focussing revealed that the microheterogeneity of liver and bile ferritin were identical, but slightly different from plasma ferritin. These results indicate that ferritin was not solely leaking from the plasma to the bile. Together with ferritin, iron accumulated in the bile. The iron content of the bile ferritin was in the same range as in fully iron-loaded liver ferritin. It is likely that ferritin in the bile is excreted by the liver and consists of normal iron-loaded liver ferritin molecules. In all circumstances, the amount of iron in the bile was much higher than could be accounted for by transport by the bile ferritin. The ferritin protein to iron ratio in the bile was 0.1-1.2, which was in the same range as was measured in isolated lysosomal fractions of the liver. Those results agree with the supposition that ferritin and iron in the bile are excreted by the liver though lysosomal exocytosis.     

Iron overload of the liver by trimethylhexanoylferrocene in rats.

Iron-deficient female Wistar rats were fed a diet, which contained 0.5% trimethylhexanoylferrocene, over a 56-week period. This dietary iron loading resulted in a progressive siderosis and enlargement of the liver with a maximum iron content of 947.0 +/- 148.0 mg (vs. 0.07 +/- 0.04 mg in iron deficiency) and a maximum organ weight of 39.4 +/- 6.6 g (vs. 6.9 +/- 1.4 g in iron-deficient control rats). Up to 43 weeks, whole liver iron rose by increase in iron concentration (max. 28.0 +/- 6.1 mg/g wet weight, w.w.) as well as by enlargement of the organ. Afterwards whole liver iron increased solely by ongoing hepatomegaly. At the commencement of iron loading, stainable iron was almost exclusively stored by hepatocytes equally throughout all areas of the liver lobule. Later, the distribution of iron-loaded hepatocytes became strikingly periportal, and, in addition, Kupffer cells as well as sinus-lining endothelia began to store iron. Animals with a liver iron concentration of more than 10.4 +/- 0.75 mg/g w.w. showed no further increase in ferritin and haemosiderin within hepatocytes. Iron-burdened Kupffer cells/macrophages, however, accumulated permanently, hereby forming intrasinusoidal and portal siderotic nodules and areas. First signs of liver damage such as necrosis of single hepatocytes and mild fibrosis began at a liver iron concentration of 14.7 +/- 1.4 mg/g w.w. With advancement of iron loading, focal necrosis of hepatocytes and iron-burdened macrophages took place, and significant perisinusoidal as well as portal fibrosis developed. Cirrhosis, however, the final stage of impairment in iron overload of the liver in humans, could not be induced in this animal model up to now.     

Gap junctions and zonulae occludentes of hepatocytes during biliary atresia in the lamprey

Gap junctions and zonulae occludentes of hepatocytes were examined in thin sections and freeze-fracture replicas from livers of larval and juvenile adult lampreys and during the phase of metamorphosis when bile ducts and bile canaliculi disappear (biliary atresia). Larvae possess zonulae occludentes at the canaliculi which are composed of one to five (mean = 2.81) junctional strands that provide a bile-blood barrier. Morphometry demonstrates that during biliary atresia the decreases in number of junctional strands and apico-basal depth of the zonulae occludentes are accompanied by an increase in the frequency of gaps or interruptions in the strands and in a breakdown of the bile-blood barrier. The zonulae occludentes completely disappear during metamorphosis and are not found in the adult liver. Gap junctions of the larval liver occupy 1% of the surface of the plasma membrane and have a mean area of 0.167 micron 2 but, following an initial decline in these parameters during early biliary atresia, they rise sharply in later stages of metamorphosis and in adults are 3.2% and 0.502 micron 2, respectively. The events of alteration in junctional morphology during lamprey biliary atresia is in many ways comparable to the changes in gap junctions and zonulae occludentes during experimental and pathological intra- and extrahepatic cholestasis in mammals.     

Intracellular distribution of iron (and associated elements) in various cell types of larvae and juveniles of the sea lamprey (Petromyzon marinus)

The intracellular distribution of iron and other elements was examined in various cell types in larvae and juveniles of the sea lamprey (Petromyzon marinus) using transmission electron microscopy and energy dispersive x-ray microanalysis. The objective was to establish whether there are cell-type specific relationships between iron and other elements in the iron-rich organs and tissues (adipose tissue, opisthonephric kidneys, dorsal integument, fat column, liver, and posterior intestine) of these two life cycle periods. Iron was localized within either dense bodies (presumptive lysosomes, siderosomes) or in the cytoplasmic matrix of many cell types where it was viewed as haemosiderin/ferritin and ferritin, respectively. Presumptive lysosomes of adipocytes of the nephric folds, dorsal integument, and fat column possessed iron and sulphur and this elemental association was also prevalent in the epithelia of the larval proximal tubules and in the posterior intestine and epidermis of both life periods. Macrophages of the larval haemopoietic tissue (posterior intestine) and of the juvenile opisthonephros, which were described as melanomacrophages because of their granules, possessed iron, sulphur, and calcium. This elemental association was also noted in the presumptive lysosomes of the iron-loaded hepatocytes of the juvenile liver while no elements could be detected in these cells in the larval organ. The variations and similarities in elemental associations between the cell types in each life period and at different life periods is discussed in the context of specific cell functions related to the prevention of iron toxicity. These functions are sequestration of iron and storage as the less toxic haemosiderin (larval adipocytes, macrophages, juvenile hepatocytes) or as part of a process of elimination of excesses of this metal (posterior intestine, dorsal epidermal cells). Due to its unique ability to deal with copious amounts of iron at all periods of the life cycle, the lamprey serves as an important model for studies of iron loading in vertebrates.     

Effects of Iron Deficiency on Serotonin Uptake In Vitro by Rat Brain Synaptic Vesicles

Abstract: The effects of moderate and severe degrees of iron deficiency on brain and liver nonhaem iron levels and 5-hydroxytryptamine (serotonin; 5-HT) uptake by synaptic vesicles in vitro were investigated in experimental rats. Data obtained suggested that in both moderate and severe forms of iron deficiency, 5-HT uptake by brain synaptic vesicles is decreased and is accompanied by a reduction in brain and liver nonhaem iron levels. On repletion with iron for 4 weeks, the deficient group of rats showed a normalisation of 5-HT uptake by synaptic vesicles and liver nonhaem iron content, whereas the brain nonhaem iron concentration still showed a significant deficit. The data thus suggest that changes in the uptake of 5-HT by brain synaptic vesicles that accompany iron depletion and repletion are more rapid than changes in the total nonhaem iron concentration in the brain. The observation that 5-HT uptake by brain synaptic vesicles is decreased in iron deficiency suggests a probable role for iron in 5-HT storage in rat brain.     

Studies on haemosiderin and ferritin from iron-loaded rat liver

Summary Haemosiderin has been isolated from siderosomes and ferritin from the cytosol of livers of rats iron-loaded by intraperitoneal injections of iron-dextran. Siderosomal haermosiderin, like ferritin, was shown by electron diffraction to contain iron mainly in the form of small particles of ferrihydrite (5Fe₂O₃ · 9H₂O), with average particle diameter of 5.36±1.31 nm (SD), less than that of ferritin iron-cores (6.14±1.18 nm). Mössbauer spectra of both iron-storage complexes are also similar, except that the blocking temperature,T _B, for haemosiderin (23 K) is lower than that of ferritin (35 K). These values are consistent with their differences in particle volumes assuming identical magnetic anisotropy constants. Measurements of P/Fe ratios by electron probe microanalysis showed the presence of phosphorus in rat liver haemosiderin, but much of it was lost on extensive dialysis. The presence of peptides reacting with anti-ferritin antisera and the similarities in the structures of their iron components are consistent with the view that rat liver haemosiderin arises by degradation of ferritin polypeptides, but its peptide pattern is different from that found in human-thalassaemia haemosiderin. The blocking temperature, 35 K, for rat liver ferritin is near to that reported, 40 K, for human-thalassaemia spleen ferritin. However, the haemosiderin isolated from this tissue, in contrast to that from rat liver, had aT _B higher than that of ferritin. The iron availability of haemosiderins from rat liver and human-thalassaemic spleen to a hydroxypyridinone chelator also differed. That from rat liver was equal to or greater, and that from human spleen was markedly less, than the iron availability from either of the associated ferritins, which were equivalent. The differences in properties of the two types of haemosiderin may reflect their origins from primary or secondary iron overload and differences in the duration of the overload.     

Non-transferrin-bound-iron in serum and low-molecular-weight-iron in the liver of dietary iron-loaded rats

• 1.1. The feeding of 0.5% (3,5,5-trimethylhexanoyl)ferrocene (TMH-ferrocene) in rats resulted in a severe and progressive liver siderosis (total liver iron, 30 mg/g liver wet weight, after 30 weeks).
• 2.2. High concentrations of an iron-rich ferritin (up to 250 mg/l) were detected in serum of heavily iron-loaded rats forming a large fraction of non-transferrin-bound-iron (5000 μg/dl in maximum).
• 3.3. Ferritin and not haemosiderin was the major iron storage protein in the liver.
• 4.4. The total liver iron concentration (from 0.4 to > 30 mg Fe/g wet wt) but not the cytosolic low-molecular-weight-iron fraction (from 0.5 to 2.5 μM) was extremely increased during iron-loading.

     

Two Transitions of Haemoglobin Expression in Xenopus: from Embryonic to Larval and from Larval to Adult

Abstract. Electrophoretic analyses of haemoglobin and globin phenotypes in families of Xenopus borealis and Xenopus l. laevis revealed two developmental haemoglobin transitions during ontogeny. The first transition occurs at the developmental stage when tadpoles begin to feed. It is characterized by the decline of embryonic-specific globins in favour of novel, tadpole-specific globins ( X. borealis ) correlated to changes in the haemoglobin pattern. We suppose that this switch results from the replacement of a primitive, ventral blood island-dependent erythrocyte population by tadpole erythrocytes from other erythropoietic sites. Several other globin chains and haemoglobins are present in both young tadpoles and throughout larval life. The second, well-known transition occurs during metamorphosis, where all tadpole haemoglobins are replaced by adult haemoglobins composed of entirely different globin chains.     

Two transitions of haemoglobin expression in Xenopus: from embryonic to larval and from larval to adult

Electrophoretic analyses of haemoglobin and globin phenotypes in families of Xenopus borealis and Xenopus l. laevis revealed two developmental haemoglobin transitions during ontogeny. The first transition occurs at the developmental stage when tadpoles begin to feed. It is characterized by the decline of embryonic-specific globins in favour of novel, tadpole-specific globins (X. borealis) correlated to changes in the haemoglobin pattern. We suppose that this switch results from the replacement of a primitive, ventral blood island-dependent erythrocyte population by tadpole erythrocytes from other erythropoietic sites. Several other globin chains and haemoglobins are present in both young tadpoles and throughout larval life. The second, well-known transition occurs during metamorphosis, where all tadpole haemoglobins are replaced by adult haemoglobins composed of entirely different globin chains.     

Haemosiderin and tissue damage

High levels of haemosiderin occur in iron overload syndromes such as idiopathic haemochromatosis or secondary iron overload in thalassaemic patients; haemosiderin is the predominant iron-storage compound in such cases. It consists of a large aggregate of FeOOH cores, many of which have an incomplete shell of protein, and is probably derived from ferritin by lysosomal proteolysis. In addition, some chemical degradation of the ferritin cores appears to occur on conversion to haemosiderin. Other biochemical components are phosphate and magnesium, which may be adsorbed to the core surface, and perhaps certain lipids. Haemosiderin may have a central role, either directly or indirectly, in iron cytotoxicity and therefore the chemistry and biochemistry of this material warrants further study.     

Proximate body composition of the larval,metamorphosing and downstream migrant stages in the life cycle of the Southern Hemisphere lamprey,Geotria australis

Synopsis The water, total lipid, protein and ash content have been measured in larval, metamorphosing (stages 1–7) and downstream migrantGeotria australis caught in Western Australia between October 1977 and August 1979. The total lipid content of ammocoetes changed markedly with season and increased with body size. Although, unlike other species, the ammocoetes ofG. australis continue to increase in length during the latter part of larval life, the relative amount of total lipid still rose during this period, eventually reaching levels equivalent to approximately 14% of the wet body weight at the commencement of metamorphosis. During the six months between the onset of metamorphosis and the downstream migration, total lipid declined to approximately 8%. Assays for phospholipid of larval and metamorphosingG. australis indicated that changes in total lipid were almost entirely due to variations in neutral lipid. Changes in the percentage amount of total lipid were accompanied by an inverse but slightly greater amount of change in percentage water. During metamorphosis, the absolute amount of total lipid in a standard animal declined from 122 mg at stage 1 to 53 mg at stage 7, whereas water rose initially from 597 mg at stage 1 to 638 mg at stage 3, before declining to 442 mg by stage 7. Although the percentage amount of protein and ash tended to increase slightly during larval life, neither showed conspicuous seasonal changes. In both relative and absolute terms, protein declined during metamorphosis. A comparison of the data on the proximate body composition inG. australis and holarctic lampreys shows that different strategies have been employed to accumulate large amounts of fat by the end of larval life and to utilize protein during metamorphosis.     

Seasonal variation in the form of iron in the liver of Spitsbergen reindeer: a M?ssbauer spectroscopic study

M?ssbauer spectra have been obtained from samples of the liver of Spitsbergen reindeer at different times of the year. Most of the iron is in a very similar form to that of the iron storage materials ferritin and haemosiderin. The data reflect the large differences in the amount of iron found in the liver at different times of the year and also indicate that there are only relatively small differences in the chemical and physical form of the iron found in the liver at different times of the year.     

Developmental fates of larval tissues after metamorphosis in the ascidian, Halocynthia roretzi

Cell lineages during ascidian embryogenesis are invariant. Developmental fates of larval mesodermal cells after metamorphosis are also invariant with regard to cell type of descendants. The present study traced developmental fates of larval endodermal cells after metamorphosis in Halocynthia roretzi by labeling each endodermal precursor blastomere of larval endoderm. Larval endodermal cells gave rise to various endodermal organs of juveniles: endostyle, branchial sac, peribranchial epithelium, digestive organs, peripharyngeal band, and dorsal tubercle. The boundaries between clones descended from early blastomeres did not correspond to the boundaries between adult endodermal organs. Although there is a regular projection from cleavage stage and larval stage to juvenile stage, this varies to some extent between individuals. This indicates that ascidian development is not entirely deterministic. We composed a fate map of adult endodermal organs in larval endoderm based on a statistical analysis of many individual cases. Interestingly, the topographic position of each prospective region in the fate map was similar to that of the adult organ, indicating that marked rearrangement of the positions of endodermal cells does not occur during metamorphosis. These findings suggest that fate specification in endoderm cells during metamorphosis is likely to be a position-dependent rather than a deterministic and lineage-based process. Received: 16 June 1999 / Accepted: 16 August 1999