Classical and intermediate monocytes scavenge non-transferrin-bound iron and damaged erythrocytes.

David Haschka,Tara L Arvedson,Clemens Feistritzer,Heinz Zoller,Thomas Sonnweber,Guenter Weiss,Markus Seifert,Benedikt Schaefer,Verena Petzer,Christoph Tschurtschenthaler,Piotr Tymoszuk,Igor Theurl,Florian Kocher,Reinhard Stauder,Sieghart Sopper

doi:10.1172/jci.insight.98867

Abstract

Myelomonocytic cells are critically involved in iron turnover as aged RBC recyclers. Human monocytes are divided in 3 subpopulations of classical, intermediate, and nonclassical cells, differing in inflammatory and migratory phenotype. Their functions in iron homeostasis are, however, unclear. Here, we asked whether the functional diversity of monocyte subsets translates into differences in handling physiological and pathological iron species. By microarray data analysis and flow cytometry we identified a set of iron-related genes and proteins upregulated in classical and, in part, intermediate monocytes. These included the iron exporter ferroportin (FPN1), ferritin, transferrin receptor, putative transporters of non-transferrin-bound iron (NTBI), and receptors for damaged erythrocytes. Consequently, classical monocytes displayed superior scavenging capabilities of potentially toxic NTBI, which were augmented by blocking iron export via hepcidin. The same subset and, to a lesser extent, the intermediate population, efficiently cleared damaged erythrocytes in vitro and mediated erythrophagocytosis in vivo in healthy volunteers and patients having received blood transfusions. To summarize, our data underline the physiologically important function of the classical and intermediate subset in clearing NTBI and damaged RBCs. As such, these cells may play a nonnegligible role in iron homeostasis and limit iron toxicity in iron overload conditions.

Highlights

Iron is essential for numerous metabolic processes, such as oxygen transport, oxidative phosphorylation, and DNA synthesis [1]
Expression of most of them peaked in the classical subset (35 genes, Figure 2). This classical monocyte-specific gene group encoded, among others, for proteins involved in iron import and intracellular trafficking (e.g., FBXL5, SLC25A37, STEAP3, STEAP4), iron export (SLC40A1 coding for the sole iron exporter FPN1), energy and steroid metabolism enzymes utilizing iron as cofactor (e.g., NDUFA11, NDUFB9, NQO1, CYP1B1), and hypoxia and inflammatory response proteins (e.g., HIF1A and MPO)
The classical monocyte FPN1 levels were transiently upregulated by iron in general and by non-transferrin-bound iron (NTBI)

Summary

Introduction

Iron is essential for numerous metabolic processes, such as oxygen transport, oxidative phosphorylation, and DNA synthesis [1]. Hepcidin expression is stimulated by high systemic iron levels [1, 4, 10] and diverse inflammatory cytokines [4, 6, 10]. Hepcidin is responsible for the systemic iron sequestration during inflammation and infection [4, 6, 9,10,11,12,13]. This mechanism is believed to have evolved as an antimicrobial defense measure and contributes to the so-called nutritional immunity [4]

Methods

Results

Conclusion