Abstract
Hereditary hemochromatosis is a genetic iron overload disease related to a mutation within the HFE gene that controls the expression of hepcidin, the master regulator of systemic iron metabolism. The natural stable iron isotope composition in whole blood of control subjects is different from that of hemochromatosis patients and is sensitive to the amount of total iron removed by the phlebotomy treatment. The use of stable isotopes to unravel the pathological mechanisms of iron overload diseases is promising but hampered by the lack of data in organs involved in the iron metabolism. Here, we use Hfe−/− mice, a model of hereditary hemochromatosis, to study the impact of the knock-out on iron isotope compositions of erythrocytes, spleen and liver. Iron concentration increases in liver and red blood cells of Hfe−/− mice compared to controls. The iron stable isotope composition also increases in liver and erythrocytes, consistent with a preferential accumulation of iron heavy isotopes in Hfe−/− mice. In contrast, no difference in the iron concentration nor isotope composition is observed in spleen of Hfe−/− and control mice. Our results in mice suggest that the observed increase of whole blood isotope composition in hemochromatosis human patients does not originate from, but is aggravated by, bloodletting. The subsequent rapid increase of whole blood iron isotope composition of treated hemochromatosis patients is rather due to the release of hepatic heavy isotope-enriched iron than augmented iron dietary absorption. Further research is required to uncover the iron light isotope component that needs to balance the accumulation of hepatic iron heavy isotope, and to better understand the iron isotope fractionation associated to metabolism dysregulation during hereditary hemochromatosis.
Highlights
Iron (Fe) homeostasis tuning is essential as Fe deficiency or excess in the body can lead to clinical severe consequences
The Fe concentration is slightly but significantly increased in Hfe−/− compared to wild type Hfe+/+ (WT) mice (Figure 2B)
We propose that the accumulation of Fe heavy isotopes in liver could be related to the Non-Transferrin Bound Iron (NTBI) known to appear in plasma when transferrin saturation increases during hemochromatosis
Summary
Iron (Fe) homeostasis tuning is essential as Fe deficiency or excess in the body can lead to clinical severe consequences. HH is mainly related to a mutation of the HFE gene that plays a role in the control of hepcidin expression, the master regulator of systemic iron metabolism. An increase of transferrin saturation exposes to Fe overload, especially in the liver, pancreas and heart [6,7,8,9,10]. Regulation of hepcidin expression plays a major role in the maintenance of Fe homeostasis since there is no, or very limited, physiological mechanisms for Fe excretion. During HH, transferrin saturation increases above 45%, leading to the appearance of abnormal biochemical forms of Fe in plasma: the Non-Transferrin Bound Iron (NTBI). NTBI that is incorporated by liver, heart and pancreas plays a major role in the development of Fe overload, especially in the liver [11,12,13]
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