Animals ; Humans ; Iron ; adverse effects ; metabolism ; Iron Overload

Hemochromatosis ; metabolism ; Humans ; Iron Overload ; Liver ; metabolism ; Male ; Middle Aged

Ineffective erythropoiesis is recognized as the principal reason of non-transfusional iron overload. In the process of expanded erythropoiesis, the apoptosis of erythroblasts induces the up-regulation of GDF15. GDF15 suppresses hepcidin production by the hepatocytes. Subsequently, low hepcidin levels increase iron absorption from the intestine resulting in iron overload. Physiological dose of GDF15 can promote the growth and differentiation of erythroid progenitors, but the high dose of GDF15 can suppress the secretion of hepcidin. The regulation of GDF15 may also be related to iron levels, epigenetic regulation and hypoxia. In this article the GDF15 and its expression and distribution, roles of GDF15 in erythropoiesis and iron overload, as well as the regulation factors of GDF15 are reviewed.
Erythropoiesis ; Growth Differentiation Factor 15 ; metabolism ; Humans ; Iron Overload

Patients with myelodysplastic syndromes (MDS) become dependent on blood transfusions and develop into transfusional iron overload, which is exacerbated by increased absorption of dietary iron in response to ineffective erythropoiesis. However, it is uncertain whether there is an association among iron accumulation, clinical complications, and decreased likelihood of survival in MDS patients. Thereby our current understanding of the effects of transfusion dependency and iron overload in MDS are discussed. Particular emphasis should be placed on further characterizing the role of redox-active forms of labile iron and oxidative stress in iron overload, decreased life expectancy and increased risk of leukemic transformation in MDS patients with iron overload.
Humans ; Iron ; metabolism ; Iron Overload ; Myelodysplastic Syndromes ; metabolism ; physiopathology ; Oxidative Stress

This study was to establish an iron overload bone marrow (BM) model by co-culturing the mononuclear cells from BM with iron, and investigate its hematopoiesis changes. The iron overload model was set up by adding different concentration of ferric citrate (FAC) into the mononuclear cells from BM and culturing for different time, and the model was confirmed by detecting labile iron pool (LIP). Then the apoptosis of hematopoietic cells, ability of hematopoietic colony forming (CFU-E, BFU-E, CFU-GM and CFU-mix) and percentage of the CD34(+) cells of the BM cells all were determined. The changes of these indexes were tested after the iron-overloaded BM was treated with deferasirox (DFO). The results showed that after BM cells were cultured with FAC at different concentrations for different time, the LIP increased in time-and concentration-dependent manners. The intracellular LIP reached maximum level when cultured at 400 µmol/L of FAC for 24 hours. The detection of BM cell hematopoietic function found that the apoptotic rate of the FAC-treated cells (24.8 ± 2.99%) increased significantly, as compared with normal control (8.9 ± 0.96%)(p < 0.01). The ability of hematopoietic colony forming in FAC-treated cells decreased markedly, as compared with normal control (p < 0.05). The percentage of CD34(+) cells of FAC-treated cells (0.39 ± 0.07%) also decreased significantly, as compared with normal control (0.91 ± 0.12%)(p < 0.01). And these changes could be alleviated by adding DFO. It is concluded that the iron-overloaded model has been set by adding iron into the mononuclear cells from BM in vitro, and the hematopoietic function of iron-overloaded BM is deficient. These changes can be alleviated by removing the excess iron from the BM cells through treating with DFO. These findings would be helpful to further study the mechanism of iron-overload on the hematopoiesis of BM and also useful to find the way to treat iron-overload patients with hematopoietic disorders.
Bone Marrow Cells ; cytology ; Cells, Cultured ; Hematopoiesis ; Hematopoietic Stem Cells ; cytology ; Humans ; Iron ; metabolism ; Iron Overload

β-thalassemia is a type of inherited hemolytic anemia caused by decreased globin production due to defect of the HBB gene. The pathogenesis of the disease is imbalance of α/β globin chains. The excess of α-globin chains will form hemichromes which can damage red blood cell membranes and lead to hemolysis, ineffective erythropoiesis, and secondary iron overload. Iron overload in turn can cause complications such as growth retardation, liver cirrhosis, cardiac insufficiency, and aggravate the disease phenotype. In recent decades, genes participating in iron metabolism have been discovered, and the mechanism of iron metabolism in the development of thalassemia has gradually been elucidated. Subsequently, by manipulating the expression of key genes in iron metabolism such as hepcidin and transferrin receptor, researchers have revealed that iron restriction can improve ineffective hematopoiesis and iron overload, which may provide a potential approach for the treatment of thalassemia. This article reviews the progress of research on iron metabolism-related genes and related pathways in β-thalassemia.
Humans ; Iron/metabolism* ; Iron Overload/genetics* ; Phenotype ; Research/trends* ; beta-Thalassemia/physiopathology*

Objective: To analyze the influencing factors of iron metabolism assessment in patients with myelodysplastic syndrome. Methods: MRI and/or DECT were used to detect liver and cardiac iron content in 181 patients with MDS, among whom, 41 received regular iron chelation therapy during two examinations. The adjusted ferritin (ASF) , erythropoietin (EPO) , cardiac function, liver transaminase, hepatitis antibody, and peripheral blood T cell polarization were detected and the results of myelofibrosis, splenomegaly, and cyclosporine were collected and comparative analyzed in patients. Results: We observed a positive correlation between liver iron concentration and ASF both in the MRI group and DECT groups (r=0.512 and 0.606, respectively, P<0.001) , only a weak correlation between the heart iron concentration and ASF in the MRI group (r=0.303, P<0.001) , and no significant correlation between cardiac iron concentration and ASF in the DECT group (r=0.231, P=0.053) . Moreover, transfusion dependence in liver and cardiac [MRI group was significantly associated with the concentration of iron in: LIC: (28.370±10.706) mg/g vs (7.593±3.508) mg/g, t=24.30, P<0.001; MIC: 1.81 vs 0.95, z=2.625, P<0.05; DECT group: liver VIC: (4.269±1.258) g/L vs (1.078±0.383) g/L, t=23.14, P<0.001: cardiac VIC: 1.69 vs 0.68, z=3.142, P<0.05]. The concentration of EPO in the severe iron overload group was significantly higher than that in the mild to moderate iron overload group and normal group (P<0.001) . Compared to the low-risk MDS group, the liver iron concentration in patients with MDS with cyclic sideroblasts (MDS-RS) was significantly elevated [DECT group: 3.80 (1.97, 5.51) g/L vs 1.66 (0.67, 2.94) g/L, P=0.004; MRI group: 13.7 (8.1,29.1) mg/g vs 11.6 (7.1,21.1) mg/g, P=0.032]. Factors including age, bone marrow fibrosis, splenomegaly, T cell polarization, use of cyclosporine A, liver aminotransferase, and hepatitis antibody positive had no obvious effect on iron metabolism. Conclusion: There was a positive correlation between liver iron concentration and ASF in patients with MDS, whereas there was no significant correlation between cardiac iron concentration and ASF. Iron metabolism was affected by transfusion dependence, EPO concentration, and RS.
Ferritins ; Humans ; Iron ; Iron Overload ; Liver/metabolism* ; Myelodysplastic Syndromes/therapy* ; Primary Myelofibrosis ; Retrospective Studies ; Splenomegaly

Ex vivo culture-amplified mesenchymal stem cells (MSCs) have been studied because of their capacity for healing tissue injury. MSC transplantation is a valid approach for promoting the repair of damaged tissues and replacement of lost cells or to safeguard surviving cells, but currently the efficiency of MSC transplantation is constrained by the extensive loss of MSCs during the short post-transplantation period. Hence, strategies to increase the efficacy of MSC treatment are urgently needed. Iron overload, reactive oxygen species deposition, and decreased antioxidant capacity suppress the proliferation and regeneration of MSCs, thereby hastening cell death. Notably, oxidative stress (OS) and deficient antioxidant defense induced by iron overload can result in ferroptosis. Ferroptosis may inhibit cell survival after MSC transplantation, thereby reducing clinical efficacy. In this review, we explore the role of ferroptosis in MSC performance. Given that little research has focused on ferroptosis in transplanted MSCs, further study is urgently needed to enhance the in vivo implantation, function, and duration of MSCs.
Humans ; Antioxidants/metabolism* ; Ferroptosis ; Mesenchymal Stem Cell Transplantation ; Mesenchymal Stem Cells ; Iron Overload/metabolism*

Humans ; Iron Overload ; diagnosis ; etiology ; therapy ; Myelodysplastic Syndromes ; diagnosis ; metabolism ; therapy

OBJECTIVETo investigate the abnormalities of iron metabolism, the prevalence and risk factors of iron overload and clinical characteristics of patients with aplastic anemia (AA).

METHODSA cross-sectional study was conducted on 520 newly diagnosed AA patients.

RESULTSIron overload was observed in 66(13%) of 520 AA patients,in which a higher prevalence of iron overload was seen not only in patients with infections(19/86, 22%)than those without infections (47/434, 11%, P<0.01), but also in patients with hepatitis associated AA(HAAA) (6/22, 19%) than the idiopathic cases (60/488, 12%, P>0.05). Excluded the patients with infections and/or HAAA, 43 of 405(11%)cases had iron overload, including 14 of 248(6%) cases without history of blood transfusion and 29 of 157 patients (18%, P<0.01) with transfusion. In univariate analysis, higher levels of serum ferritin (SF), serum iron (SI) and transferrin saturation (TS) were mainly observed in adult male patients with severe AA (SAA) and significantly upward with increasing blood transfusion (P<0.01). No differences of soluble transferrin receptor (sTfR) were observed between adults and children, males and females, hepatitis and idiopathic AA. However, patients with infections had significantly lower level of sTfR (0.50 mg/L) than cases without infections (0.79 mg/L, P<0.01). The level of sTfR in SAA patients (0.70 mg/L) was only half of that in non-SAA (NSAA) (1.36 mg/L, P<0.01). Patients with increasing blood transfusion had significantly downward levels of sTfR (P<0.01). In multivariate analysis, more than 8 U blood transfusion (OR=10.52, P<0.01), adults (OR=3.48, P<0.01), males (OR=3.32, P<0.01) and infections (OR=2.09, P<0.01) were independent risk factors.

CONCLUSIONAA patients had higher iron burden and were high-risk populations occurring iron overload. The iron overload occurred in 18% of patients with blood transfusion and in 6% of patients without transfusion.

Anemia, Aplastic ; complications ; physiopathology ; Blood Transfusion ; Ferritins ; blood ; Hepatitis ; complications ; Humans ; Iron ; blood ; metabolism ; Iron Overload ; physiopathology ; Risk Factors