Selenium is an essential immunonutrient which holds the human's metabolic activity with its chemical bonds. The organic forms of selenium naturally present in human body are selenocysteine and selenoproteins. These forms have a unique way of synthesis and translational coding. Selenoproteins act as antioxidant warriors for thyroid regulation, male-fertility enhancement, and anti-inflammatory actions. They also participate indirectly in the mechanism of wound healing as oxidative stress reducers. Glutathione peroxidase (GPX) is the major selenoprotein present in the human body, which assists in the control of excessive production of free radical at the site of inflammation. Other than GPX, other selenoproteins include selenoprotein-S that regulates the inflammatory cytokines and selenoprotein-P that serves as an inducer of homeostasis. Previously, reports were mainly focused on the cellular and molecular mechanism of wound healing with reference to various animal models and cell lines. In this review, the role of selenium and its possible routes in translational decoding of selenocysteine, synthesis of selenoproteins, systemic action of selenoproteins and their indirect assimilation in the process of wound healing are explained in detail. Some of the selenium containing compounds which can acts as cancer preventive and therapeutics are also discussed. These compounds directly or indirectly exhibit antioxidant properties which can sustain the intracellular redox status and these activities protect the healthy cells from reactive oxygen species induced oxidative damage. Although the review covers the importance of selenium/selenoproteins in wound healing process, still some unresolved mystery persists which may be resolved in near future.
Steady State erythropoiesis occurs in the bone marrow and is primarily homeostatic. In response to anemic stress the need for new erythrocytes quickly outpaces the erythropoietic capacity of steady state erythropoiesis. At these times, stress erythropoiesis predominates. Stress erythropoiesis is best understood in mice where this process is primarily extra-medullary occurring in the adult spleen and liver and in the fetal liver during development. Stress erythropoiesis utilizes progenitors and signals that are distinct from steady state erythropoiesis. Using a variety of experimental systems, we have developed a model for stress erythropoiesis during the recovery from anemic stress. This recovery can be divided into three stages. Amplification of progenitors that exhibit stem cell properties, the induction of a signal that promotes the switch from amplifying stress progenitors to differentiating stress progenitors and the final stage where stress progenitors rapidly differentiate into new erythrocytes. We have identified specific stress progenitor populations at each stage on this process as well as the signals that regulate the amplification, the switch to differentiation and differentiation of stress erythroid progenitors. Here we show that macrophage dependent signals play key roles at each stage of stress erythropoiesis. The transition from amplifying stress erythroid progenitors to differentiating stress erythroid progenitors is mediated by Epo dependent signaling in macrophages which changes the signals made by the macrophage microenvironment from those that promote amplification (Wnt family factors) to those that promote differentiation (PGE2). This paradigm is true for murine and human stress erythroid progenitors. This analysis reveals a dynamic interplay between progenitor cells, the macrophage microenvironment and hypoxic tissues in vivo during the recovery from anemic stress. Disclosures: No relevant conflicts of interest to declare.
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