Transferrin uptake by bone marrow macrophages is independent of the degree of iron saturation

Secretion of growth factors from macrophages when cultured with microparticles

The aim of this study is to investigate the influence of macrophages on osteoblast (OB) performance and differentiation. In this regard, we studied the secretion of growth factors including bone morphogenetic proteins (BMPs) from before and after activation of macrophages. We also evaluated osteogenic markers in the co-culture of macrophages and OBs. The macrophages were seeded on microparticles (MPs) based on chitosan (CS). Two types of MPs were fabricated including CS MPs and 10% calcium phosphate (CaHPO4 )-incorporated CS MPs. Macrophage seeded on MPs was activated using lipopolysaccharide (LPS). The expression of BMP-2, BMP-6, BMP-7, and transforming growth factor beta (TGF-β) from macrophages seeded and cultured on hybrid MPs before and after activation of LPS at predetermined times was quantified using a quantitative reverse transcription-polymerase chain reaction (RT-PCR). All of the above growth factors were expressed from MP-macrophage cultures before LPS activation. Osteogenic markers such as alkaline phosphatase (ALP), osteocalcin (OCN), and collagen I (COL-I) in the cultures of MP-OB-macrophage were quantified using a quantitative RT-PCR at days 2, 4, and 7. We found an elevation of gene expression of ALP and COL-1 in the co-cultures of OB-macrophage on MPs compared to OB on MP cultures. These data suggest that macrophages enhance expression of osteogenic markers in OBs, and demonstrate the importance of the role of macrophages in bone regeneration.

Use and endocytosis of iron-containing proteins by Entamoeba histolytica trophozoites

Iron is essential for nearly all organisms; in mammals, it is part of proteins such as haemoglobin, and it is captured by transferrin and lactoferrin. Transferrin is present in serum, and lactoferrin is secreted by the mucosa and by neutrophils at infection sites, as a host iron-withholding response, sequestering iron away from invading microorganisms. Additionally, all cells contain ferritin, which sequesters iron when its intracellular levels are increased, detoxifying and preventing damage. Liver ferritin contains 50% of iron corporal reserves. During evolution, pathogens have evolved diverse strategies to obtain iron from their hosts in order to survive. The protozoan Entamoeba histolytica invades the intestinal mucosa, causing dysentery, and the trophozoites often travel to the liver producing hepatic abscesses; thus, intestine and liver proteins could be important iron supplies for E. histolytica. We found that E. histolytica trophozoites can grow in both ferrous and ferric iron, and that they can use haemoglobin, holo-transferrin, holo-lactoferrin, and ferritin as in vitro iron sources. These proteins supported the amoeba growth throughout consecutive passages, similarly to ferric citrate. By confocal microscopy and immunoblotting, iron-binding proteins were observed specifically bound to the amoeba surface, and they were endocytosed, trafficked through the endosomal/lysosomal route, and degraded by neutral and acidic cysteine-proteases. Transferrin and ferritin were mainly internalized through clathrin-coated vesicles, and holo-lactoferrin was mainly internalized by caveola-like structures. In contrast, apo-lactoferrin bound to membrane lipids and cholesterol, inducing cell death. The results suggest that in vivo trophozoites secrete products that can destroy enterocytes, erythrocytes, and hepatocytes, releasing transferrin, haemoglobin, ferritin, and other iron-containing proteins, which, together with lactoferrin derived from neutrophils and acinar cells, could be used as abundant iron supplies by amoebas.

Entamoeba histolytica: Comparison of the role of receptors and filamentous actin among various endocytic processes

Entamoeba histolytica is the causative agent of amoebic dysentery. Uptake of iron is critical for E. histolytica growth and iron-bound human transferrin (holo-transferrin) has been shown to serve as an iron source in vitro. Although a transferrin-binding protein has been identified in E. histolytica, the mechanism by which this iron source is taken up by this pathogen is not well understood. To gain insight into this process, the uptake of fluorescent-dextran, -holo-transferrin, and human red blood cells (hRBCs) was compared. Both dextran and transferrin were taken up in an apparent receptor-independent fashion as compared to hRBCs, which were taken up in a receptor-mediated fashion. Interestingly, the uptake of FITC-dextran and FITC-holo-transferrin differentially relied on an intact actin cytoskeleton suggesting that their internalization routes may be regulated independently.

Apotransferrin is internalized and distributed in the same way as holotransferrin in K562 cells

Transferrin (Tf), a naturally existing protein, has received considerable attention in the area of drug targeting since it is biodegradable, non-toxic, and non-immunogenic. The efficient cellular uptake of Tf shows it has potential in the delivery of anti-cancer drugs, proteins, and therapeutic genes into proliferating malignant cells that overexpress transferrin receptor (TfR). In human serum, about 30% of Tf exists in the iron-saturated form (Fe(2)-Tf) and the remainder exists as apotransferrin (apo-Tf). Understanding the uptake of apo-Tf by cells will provide key insights into studies on Tf-mediated drug delivery. In the present study, we investigated visually the transport of apo-Tf into K562 cells and its intracellular localization by laser-scanning confocal microscopy (LSCM) and flow cytometry analysis (FCA). It was found that, like Fe(2)-Tf, apo-Tf can be taken up into the cells. The process is time- and temperature-dependent, competitively inhibited by Fe(2)-Tf, and significantly abolished by pronase pretreatment. Visual evidence showed that the transport of apo-Tf into K562 cells is a TfR-mediated process. Furthermore, the investigations using optical-slicing technique demonstrated that the distribution of apo-Tf is similar to that of Fe(2)-Tf, both appearing in the perinuclear region in ball-in-bowl shape.

Regulation of mammalian iron metabolism: current state and need for further knowledge

Due to its character as an essential element for all forms of life, the biochemistry and physiology of iron has attracted very intensive interest for many decades. In more recent years, the ways that iron metabolism is regulated in mammalian and human organisms have been clarified, and many aspects of iron metabolism have been reviewed. In this article, some newer aspects concerning absorption and intracellular regulation of iron concentration are considered. These include a sorting of possible models for intestinal iron absorption, a description of ways for membrane passage of iron after release from transferrin during receptor-mediated endocytosis, a consideration of possible mechanisms for non-transferrin bound iron uptake and its regulation, and a review of recent knowledge on the properties of iron regulatory proteins and on regulation of iron metabolism by these proteins, changes of their own properties by non-iron-mediated influences, and regulatory events not mediated by these proteins. This somewhat heterogeneous collection of themes is a consequence of the intention to avoid repetition of the many aforementioned reviews already existing and to concentrate on newer findings generated within the last couple of years.

Uptake of iron from N-terminal half-transferrin by isolated rat hepatocytes. Evidence of transferrin-receptor-independent iron uptake

The aim of the present study was to determine if human N-terminal half-transferrin (N- fragment), prepared by thermolysin cleavage of diferric transferrin, would bind to the rat hepatocyte transferrin receptor and donate iron to the cell. Competition experiments between 125I-labelled N-fragment and diferric transferrin revealed no receptor binding of the half-transferrin. Still, the N-fragment delivered iron to the cells in amounts approximately 30-fold above what could be accounted for by uptake of the fragment itself. The rate of cellular iron uptake from the fragment was comparable to what is seen with the intact transferrin. The uptake of 125I-labelled N-fragment was not inhibited by excess non-radioactive diferric transferrin. By comparison, the uptake of 59Fe from the N-fragment was inhibited 70% by excess nonradioactive diferric transferrin. This suggests that iron derived from diferric transferrin competes with the iron derived from the N-fragment for a common transport pathway. Although some cellular degradation of the N-fragment occurred, the extent of degradation was too low to explain the amount of iron accumulated by the cells. The results show that the hepatocyte has an effective transferrin-receptor-independent mechanism for accumulation of iron from transferrin.