Regulación del metabolismo del hierro: dos sistemas, un mismo objetivo / Iron metabolism regulation: two systems, one goal

La existencia humana está indisolublemente unida al hierro, que es parte de una amplia variedad de enzimas claves como catalasas, aconitasas, ribonucleótido reductasa, peroxidasas y citocromos, que explotan la flexibilidad de su química redox para ejecutar un elevado número de reacciones esenciales para la vida. El cuerpo humano ha evolucionado para conservar el hierro en diferentes formas, incluido su reciclaje después de la ruptura de los eritrocitos y la retención en ausencia de un mecanismo de excreción. El metabolismo del hierro está balanceado por dos sistemas regulatorios: uno sistémico basado en la hormona hepcidina y la proteína exportadora ferroportina, y el otro que controla el metabolismo celular través de las proteínas reguladoras de hierro (IRP) que se unen a los elementos de respuesta al hierro (IRE) de los ARNm regulados. Estos sistemas funcionan de modo coordinado lo que evita, tanto la deficiencia como el exceso del mineral(AU)

Human existence is indissolubly linked to iron, which is part of a wide variety of key enzymes such as catalase, aconitases, ribonucleotide reductase, peroxidases and cytochromes, exploiting the flexibility of its redox chemistry to run a large number of reactions essential for life. Human body has evolved to keep iron in different forms, including recycling after rupture of erythrocytes and the retention without excretion mechanism. Iron metabolism is balanced by two regulatory systems: one based on systemic hormone hepcidin protein export and ferroportin, and the other, which controls cell metabolism through the iron regulatory protein (IRP) binding to the mRNAs regulated iron regulatory elements (IRE). These systems work in a coordinated manner avoiding both deficiency and excess(AU)

Sox2 function as a negative regulator to control HAMP expression

BACKGROUND: Hepcidin, encoding by HAMP gene, is the pivotal regulator of iron metabolism, controlling the systemic absorption and transportation of irons from intracellular stores. Abnormal levels of HAMP expression alter plasma iron parameters and lead to iron metabolism disorders. Therefore,itis animportant goal to understand the mechanisms controlling HAMP gene expression. RESULTS: Overexpression of Sox2 decrease basal expression of HAMP or induced by IL-6 or BMP-2, whereas, knockdown of Sox2 can increase HAMP expression, furthermore, two potential Sox2-binding sites were identified within the human HAMP promoter. Indeed, luciferase experiments demonstrated that deletion of any Sox2-binding site impaired the negative regulation of Sox2 on HAMP promoter transcriptional activity in basal conditions. ChIP experiments showed that Sox2 could directly bind to these sites. Finally, we verified the role of Sox2 to negatively regulate HAMP expression in human primary hepatocytes. CONCLUSION: We found that Sox2 as a novel factor to bind with HAMP promoter to negatively regulate HAMP expression, which may be further implicated as a therapeutic option for the amelioration of HAMP-overexpression-related diseases, including iron deficiency anemia.

Anemia de las enfermedades crónicas asociada a obesidad: papel de la hepcidina como mediador central / Hepcidin as a central mediator of anemia of chronic diseases associated with obesity

Recent evidence suggests that obesity-related inflammation may play a central role in hepcidin regulation. Hepcidin is a key regulator ofiron homeostasis and has now been suggested as a central mediator ofiron metabolism disorders involved in the pathogenesis of anemia of chronic disease. In this review, we focus on subclinical inflammation in obesity and its effect on hepcidin levels, as the most plausible explanation for the relationship between anemia of chronic disease and obesity.