Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0240066 (iron deficiency)
7,156 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The aim of this investigation was to establish the relationship of cadmium-induced fetal growth retardation in the mouse to iron deficiency. Pregnant mice were either fed a low iron diet or given 40 ppm cadmium in their drinking water. The effects of these factors on fetal weight and hematological values of the fetuses and dams were established and compared, both with each other and with appropriate controls. Both treatments caused maternal and fetal anemia, the fetuses being more severely affected. The anemic fetuses were also severely growth retarded. These changes, when caused by the iron deficient diet, could be completely prevented by either parenterally or orally administered iron supplements. When the changes were caused by cadmium in the drinking water they were only partially prevented by oral supplements. From these results it was concluded that iron deficiency in pregnancy causes not only anemia but also fetal growth retardation. Cadmium exposure in pregnancy, presumably by blocking intestinal absorption of iron, also causes anemia and hence fetal growth retardation.
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PMID:Iron deficiency and its role in cadmium-induced fetal growth retardation. 47 57

In mice fed a low iron diet, the addition of low levels of cadmium chloride (10 micrometer) to the drinking water impaired growth and accentuated the development of anemia. Cadmium had no effect on mice given a similar diet supplemented with iron. Iron deficiency increased the concentration of cadmium in the duodenal mucosa, the transfer of cadmium to the body from the intestinal tract, and the deposition of absorbed cadmium in the kidneys. In human subjects, the average absorption of 25 microgram of cadmium, labeled with 115mCd, from a test meal was 8.9 +/- 2.0% (mean +/- SE) in 10 people with low body iron stores (serum ferritin less than 20 ng per ml) and 2.3 +/- 0.3% in 12 subjects with normal iron stores (serum ferritin greater than 23 ng per ml). The biological half-time of the radiocadmium in 3 of the subjects ranged from 90 to 202 days. Thus, the intestinal adaptive response to iron deficiency in both experimental animals and human subjects leads to the increased absorption of cadmium, a potentially toxic element.
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PMID:Increased dietary cadmium absorption in mice and human subjects with iron deficiency. 64 Mar 39

Zinc absorption from a test dose of (65Zn) zinc chloride was increased in mice with a high capacity to absorb iron induced by a low-iron diet. When radiolabelled zinc chloride in concentrations varying from 0.025 to 0.30 mM was perfused through open-ended duodenal loops of mice fed this diet, the proportion of zinc taken up from the lumen and transferred to the body was greater from lower than from higher doses. The addition of iron to the perfusate inhibited zinc uptake and transfer, and zinc had a similar effect on iron absorption. Cadmium, a potent inhibitor of iron uptake in mice fed a low-iron diet, impaired zinc uptake under these dietary conditions. These results suggest that in dietary-induced iron deficiency there are analogous mucosal binding sites for the uptake of iron and zinc. There also appear to be mutually exclusive binding sites for the absorption of these metals: radiolabelled iron absorption from an intragastric test dose was enhanced in mice with a high capacity to absorb iron produced by bleeding, whereas the absorption of zinc was not increased.
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PMID:Zinc, cadmium, and iron interactions during intestinal absorption in iron-deficient mice. 66 12

In order to evaluate the effects of iron deficiency on the absorption of pollutant metals, an iron-deficient diet was fed to young rats until their tissue-iron stores were depleted. Prior to the development of anemia, the iron-deficient rats and littermate controls were administered an intragastric gavage of lead-210 or cadmium-109 and were killed 48 hr later. The body burden of lead was approximately 6 times greater, and that of cadmium approximately 7 times greater, in iron-deficient rats than in the controls. No consistent effects were observed on concentrations of serum total lipids or serum proteins nor on protein electrophoretic patterns in rats with a deficit in iron stores.
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PMID:Effects of iron deficiency on the absorption and distribution of lead and cadmium in rats. 90 99

The average gastrointestinal uptake 4 h after an intragastric dose of 400 nmol of cadmium chloride labeled with 109CdCl2 in iron-deficient mice, 25%, was significantly greater than the result, 16%, in iron-normal animals, and more cadmium entered the body of the former, 3.8%, than the latter, 2% (P less than 0.05). Between 4 and 72 h, gastrointestinal radioactivity declined without further increase in body activity; however, more radiocadmium remained in the duodenum of iron-deficient than iron-normal animals (P less than 0.05). The radiocadmium sequestered in the duodenum was bound to a protein with a molecular weight of about 12,000. After subcutaneous injection of radiocadmium, the rate of excretion of radioactivity from the body was similar in iron-normal and iron-deficient mice; however, a greater proportion of the injected dose accumulated in the duodenum of the iron-deficient animals (P less than 0.05). Thus, the intestinal adapative response to iron deficiency may enhance cadmium toxicity, whereas sequestration and subsequent excretion of cadmium by the intestinal mucosa serves to protect the body against toxic effects. The duodenum, particularly in iron-deficient mice, is especially vulnerable to the toxic effects of cadmium.
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PMID:Gastrointestinal metabolism of cadmium in experimental iron deficiency;. 96 98

The retention of cadmium was investigated in cadmium-naive normal and iron-deficient rats in comparison to rats with cadmium-induced iron deficiency. Rats subchronically (4 weeks) exposed to dietary cadmium (28, 56, 112 ppm Cd and 28 ppm Fe) received a radioactively labeled dose of 2 mumol Cd/kg body wt; acutely (no cadmium exposure with diet) treated rats received doses between 1 and 8 mumol Cd/kg body wt. Two animals of each group received iron (1 mumol/kg as 59FeSO4 in order to monitor iron absorption in parallel. After a period of 4 weeks of feeding a cadmium-fortified diet, the test dose was administered and after a 2-weeks period 109Cd and of 59Fe retention was determined. The results showed in part an unexpected pattern of cadmium retention: subchronic feeding of cadmium induced iron deficiency. This implies an immediate interaction between the two metals with regard to intestinal transfer of iron. The retention of iron was increased in the Cd-induced anemia to the same extent as that in iron deficiency induced by iron restriction. Cadmium retention in iron deficiency induced by iron withdrawal also showed a marked increase, which implies that iron deficiency stimulates the intestinal transfer system for both metals in a similar way. Contrary to this effect, the cadmium retention in cadmium-induced iron deficiency was reduced to about 30% of control values. A self-induced aggravation of the body cadmium burden, as a consequence of the iron deficiency which is known to result from subchronic exposure to feeding of dietary cadmium, was thus excluded.
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PMID:Retention of cadmium in cadmium-naive normal and iron-deficient rats as well as in cadmium-induced iron-deficient animals. 222 45

Seven different metals (iron, copper, zinc, calcium, manganese, lead, and cadmium) were studied in eight different brain regions (cerebral cortex, cerebellum, corpus striatum, hypothalamus, hippocampus, midbrain, medulla oblongata, and pons) of weaned rats (21-d-old) maintained on an iron-deficient (18-20 mg iron/kg) diet for 8 wk. Iron was found to decrease in all the brain regions, except medulla oblongata and pons, in comparison to their respective levels in control rats, receiving an iron-sufficient (390 mg iron/kg) diet. Brain regions showed different susceptibility toward iron deficiency-induced alterations in the levels of various metals, such as zinc, was found to increase in hippocampus (19%, p less than 0.05) and midbrain (16%, p less than 0.05), copper in cerebral cortex (18%, p less than 0.05) and corpus striatum (16% p less than 0.05), calcium in corpus striatum (22%, p less than 0.01) and hypothalamus (17%, p less than 0.02), and manganese in hypothalamus (18%, p less than 0.05) only. Toxic metals lead and cadmium also increased in cerebellum (19%, p less than 0.05) and hippocampus (17%, p less than 0.05) regions, respectively. Apart from these changes, liver (64%, p less than 0.001) and brain (19%, p less than 0.01) nonheme iron contents were found to decrease significantly, but body, liver, and brain weights, packed cell volume, and hemoglobin content remained unaltered in these experimental rats. Rehabilitation of iron-deficient rats with an iron-sufficient diet for 2 wk recovered the values of zinc in both the hippocampus and mid-brain regions and calcium in the hypothalamus region only. Liver nonheme iron improved significantly; however, no remarkable effect was noticed in brain nonheme iron following rehabilitation. It may be concluded that latent iron deficiency produced alterations in various metal levels in different brain regions, and corpus striatum was found to be the most vulnerable region for such changes. It is also evident that brain regions were resistant for any recovery in their altered metallic levels in response to rehabilitation for 2 wk.
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PMID:Effect of latent iron deficiency on metal levels of rat brain regions. 248 35

Studies were conducted to determine the effect of dietary iron (Fe) levels ranging from a deficiency to an excess on the toxicity of cadmium (Cd) in chicks. In Fe-deficient animals, cadmium was found to be more toxic than in Fe supplemented animals as measured by growth. The liver Cd burdens were increased significantly in the presence of dietary Fe supplementation, and there was a significant Cd-Fe interaction in the Cd concentration of the kidney, indicating that iron deficiency increased the concentration of Cd in the kidneys of those chicks receiving this element. Cd tended to reduce the Fe concentration in both the liver and kidney. The absorption of Cd as measured by the amount of 109Cd that disappeared from an isolated duodenal segment in one h was not affected by the Fe content of the diet, but the amount of isotope appearing in the liver compared to the amount present in the blood was increased in the Fe supplemented chicks. Separation of the Cd binding ligands by column chromatography revealed that more of the Cd in the liver, but not the kidney, was associated with ligands which eluted in a column volume that contained metallothionein in those chicks receiving Fe than in the livers from Fe deficient animals. The inverse relationship between the amount of Cd bound to the metallothionein containing fraction and toxicity may be related causally.
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PMID:Studies on the role of iron in the reversal of cadmium toxicity in chicks. 248 63

Iron metabolism in the Belgrade rat was examined in the intact animal and in the reticulocyte suspensions. The plasma iron turnover was increased. However, when allowance was made for the effect of the elevated plasma iron concentration, erythroid marrow capacity for iron uptake was at basal levels. Numbers of erythroid cells in marrow and spleen measured by the radioiron dilution technique were increased. Thus iron uptake was not proportionate to the erythroid hyperplasia in the b/b rat, despite a more than adequate plasma iron supply. This relative deficiency in iron uptake was reflected in a severe microcytosis and elevated red cell protoporphyrin. Reticulocyte incubation studies demonstrated an unimpaired uptake of the transferrin-iron-receptor complex but a marked reduction in iron accumulation. The diferric transferrin molecule, when it did give up iron within the cell, released both of its iron atoms so that only apotransferrin was returned to the media. In contrast to the nearly complete release of iron within the normal reticulocyte, the major portion of iron taken up by the Belgrade reticulocyte was returned to the plasma. The release mechanism that can be impaired in iron-deficient reticulocytes by EDTA or cadmium was shown to be affected by lower concentrations of these substances in the Belgrade reticulocyte. It is concluded that the Belgrade rat has an abnormality of iron release within the absorptive vacuole that is responsible for a state of intracellular iron deficiency, involving the erythron and other body tissues.
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PMID:Iron metabolism in the Belgrade rat. 308 Oct 63

Effects of cadmium (Cd) on in vitro and in vivo erythropoiesis in rats were studied by methylcellulose colony assay. Cd suppressed the in vitro growth of late erythroid progenitors (CFU-E) in a dose-dependent fashion and did not lose its inhibitory potency with increasing doses of erythropoietin (EPO). In addition, in marrow suspension cultures, Cd did not significantly influence 59Fe incorporation into both the cells and heme, and the Cd dose-responsive inhibition curve of the number of living cells was similar to that of CFU-E. These results suggest that the suppression of CFU-E colony formation by Cd is not due to the blocking of either EPO action to stimulate the growth of CFU-E or the iron incorporation into the cells ahd heme, but due to its direct cytotoxic effect. The colony suppression by Cd could be prevented by adding metallothionein to the cultures. On the other hand, oral administration of Cd to animals (100 mg/liter in drinking water) induced an iron deficiency anemia characterized by microcytic hypochromic red cells, decreased plasma iron, and increased total iron binding capacity. Marrow CFU-E density steadily increased as plasma iron decreased due to Cd administration and reached a plateau after 50 days. Plasma EPO titers were also found to be elevated in such a Cd-induced anemia. Parenteral iron administration during the Cd drinking period could completely prevent the development of iron deficiency anemia and the increase of both CFU-E and plasma EPO. There was a hyperbolic correlation between CFU-E and plasma iron or transferrin saturation. These results demonstrate that oral CD administration produces bone marrow hyperplasia at the CFU-E level due to iron deficiency.
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PMID:Effects of cadmium on in vitro and in vivo erythropoiesis: erythroid progenitor cells (CFU-E), iron, and erythropoietin in cadmium-induced iron deficiency anemia. 339 Dec 51


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