2.A.100 The Ferroportin (Fpn) Family The Ferroportin Family is called the FPN1 family in Pfam. Ferroportin 1, also called FPN1, IREG1 or MTP1 (Slc11a3; Slc40a1) (570 aas) is an iron-regulated transporter that is found in the basolateral membranes of intestinal epithilia and in phagocytic cells of the reticuloendothelial system of mammals (Delaby et al., 2007). The protein catalyzes exit of divalent metal ions from the epithelial cell into the tissues. Orthologues in the mouse and humans have been characterized. Homologues are found in a variety of plants and animals. These proteins are of between 400 and 800 aas and exhibit 8-11 putative TMSs. IREG1 appears to have 10 - 12 TMSs based on hydropathy plots. Because ferroportin extrudes Fe²⁺ from the cell which has a membrane potential negative inside, ferroportin is presumed to function by cation (H⁺ or Na⁺) antiport. Studies with antisera to different epitopes of ferroportin (Fpn) indicated that it has 11 TMSs, with the C-terminus exposed on the cell surface (Yeh et al., 2011). Iron release from macrophages after erythrophagocytosis via ferroportin in the basolateral membrane is up-regulated by ferroportin 1 overexpression and down-regulated by hepcidin (Knutson et al. 2005). Ferroportin is proposed to function in intestinal iron absorption as follows: (1) Fe³⁺ is reduced to Fe²⁺ by a ferric reductase localized to the apical membrane. (2) Fe²⁺ crosses the brush boarder membrane via the proton-coupled divalent cation transporter, DCT1 (TC# 2.A.55.2.2). (3) Fe²⁺ is exported across the basolateral membrane via FPN1 (IREG1). (4) A copper oxidase, hephaestin, converts Fe²⁺ to Fe³⁺ in preparation for binding by circulating transferrin. The liver-secreted peptide hormone, Hepcidin, binds to ferroportin, promoting internalization and degradation (Chen and Enns, 2011). Ferroportin can also function as a manganese exporter (Madejczyk and Ballatori, 2011). Reduced interactions between ferroportin and Hephaestin after iron ingestion indicated that dissociation is a regulatory mechanism for limiting further iron absorption (Yeh et al., 2011). Ferroportin-1 is associated with excess iron deposits in human macrophages. It plays an essential role in iron recycling from erythrophagocytosed red cells. Its expression is regulated by increasing cytoplasmic iron or copper (Chung et al., 2004). Its expression after erythrophagocytosis in mouse macrophages is induced early by heme, followed by iron-mediated, post-transcriptional regulation of the exporter (Delaby et al., 2007). The distribution of DMT1 and ferroportin (FPN) in the apical versus basolateral membranes has been studied as a function of iron supply with surprising observations (Núñez et al., 2010). There are two closely related paralogs of mammalian ferroportin (FPN) in Arabidopsis thaliana, IRON REGULATED1 (IREG1/FPN1) and IREG2/FPN2 (Morrissey et al., 2009). FPN1 localizes to the plasma membrane and is expressed in the stele, suggesting a role in vascular loading; FPN2 localizes to the vacuole and is expressed in the two outermost layers of the root in response to iron deficiency, suggesting a role in buffering metal influx. Consistent with these roles, fpn2 has a diminished iron deficiency response, whereas fpn1 fpn2 has an elevated iron deficiency response. Ferroportins also play a role in cobalt homeostasis; a survey of Arabidopsis accessions for ionomic phenotypes showed that truncation of FPN2 results in elevated shoot cobalt levels and leads to increased sensitivity to the metal. Conversely, loss of FPN1 abolishes shoot cobalt accumulation, even in the cobalt accumulating mutant frd3. Consequently, in the fpn1 fpn2 double mutant, cobalt cannot move to the shoot via FPN1 and is not sequestered in the root vacuoles via FPN2; instead, cobalt likely accumulates in the root cytoplasm causing fpn1 fpn2 to be even more sensitive to cobalt than fpn2 mutants. (Morrissey et al., 2009). Ca²⁺ is required for human Fpn-mediated transport activity, and iron efflux is stimulated by extracellular Ca²⁺ in the physiological range of Ca²⁺, even though it is not transported. Deshpande et al. 2018 determined the crystal structure of a Ca²⁺-bound BbFpn, a prokaryotic orthologue (TC# 2.A.100.2.1), and found that Ca²⁺ is a cofactor that facilitates a conformational change critical to the transport cycle. They also identified a substrate pocket accommodating a divalent transition metal complexed with a chelator. These findings support a model of iron export by Fpn and suggest a link between plasma calcium and iron homeostasis (Deshpande et al. 2018). Dendritic cell-derived hepcidin acted on ferroportin-producing phagocytes to promote local iron sequestration, preventing iron uptake by bacteria, and promoting intestinal musal healing (Bessman et al. 2020). Hepsidin induces ferroportin degradation, and thus intracellular retention in cells, but in the absence of hepcidin, iron is released from the cells (Rescigno 2020). The role of the discontinuous TMS7 helix of human ferroportin involves formation of a salt-bridge between TMS1 and TMS7b during iron translocation, and the lack of this salt bridge might lead to protein instability (Le Tertre et al. 2021). Mouse ferroportin has been incorporated into saposin A picodiscs (see TC# 8.D.4 (Zhou et al. 2021). Alternative splicing generates a novel ferroportin isoform with a shorter C-terminal and intact iron- and hepcidin-binding properties (Juneja et al. 2024). The transport reaction catalyzed by Ferroportin is: Fe²⁺ (in) + nH⁺ (out) ⇌ Fe²⁺ (out) + nH⁺ (in)
This family belongs to the Major Facilitator (MFS) Superfamily.
References:
Anderson, G.J., D.M. Frazer, A.T. McKie, S.J. Wilkins, and C.D. Vulpe. (2002). The expression and regulation of the iron transport molecules hephaestin and IREG1: implications for the control of iron export from the small intestine. Cell Biochem. Biophys. 36: 137-146.
Bessman, N.J., J.R.R. Mathieu, C. Renassia, L. Zhou, T.C. Fung, K.C. Fernandez, C. Austin, J.B. Moeller, S. Zumerle, S. Louis, S. Vaulont, N.J. Ajami, H. Sokol, G.G. Putzel, T. Arvedson, R.E. Sockolow, S. Lakhal-Littleton, S.M. Cloonan, M. Arora, C. Peyssonnaux, and G.F. Sonnenberg. (2020). Dendritic cell-derived hepcidin sequesters iron from the microbiota to promote mucosal healing. Science 368: 186-189.
Chen J. and Enns CA. (2012). Hereditary hemochromatosis and transferrin receptor 2. Biochim Biophys Acta. 1820(3):256-63.
Chen, H., T. Su, Z.K. Attieh, T.C. Fox, A.T. McKie, G.J. Anderson, and C.D. Vulpe. (2003). Systemic regulation of HEPHAESTIN and IREG1 revealed in studies of genetic and nutritional iron deficiency. Blood 102: 1893-1899.
Chung, J., D.J. Haile, and M. Wessling-Resnick. (2004). Copper-induced ferroportin-1 expression in J774 macrophages is associated with increased iron efflux. Proc. Natl. Acad. Sci. USA 101: 2700-2705.
Cioffi, A.G., J. Hou, A.S. Grillo, K.A. Diaz, and M.D. Burke. (2015). Restored Physiology in Protein-Deficient Yeast by a Small Molecule Channel. J. Am. Chem. Soc. 137: 10096-10099.
Conte, S., D. Stevenson, I. Furner, and A. Lloyd. (2009). Multiple antibiotic resistance in Arabidopsis is conferred by mutations in a chloroplast-localized transport protein. Plant Physiol. 151: 559-573.
Delaby, C., N. Pilard, H. Puy, and F. Canonne-Hergaux (2008). Sequential regulation of ferroportin expression after erythrophagocytosis in murine macrophages: early mRNA induction by haem, followed by iron-dependent protein expression. Biochem J 411: 123-31.
Deshpande, C.N., T.A. Ruwe, A. Shawki, V. Xin, K.R. Vieth, E.V. Valore, B. Qiao, T. Ganz, E. Nemeth, B. Mackenzie, and M. Jormakka. (2018). Calcium is an essential cofactor for metal efflux by the ferroportin transporter family. Nat Commun 9: 3075.
Fraenkel, P.G., D. Traver, A. Donovan, D. Zahrieh, and L.I. Zon. (2005). Ferroportin1 is required for normal iron cycling in zebrafish. J Clin Invest 115: 1532-1541.
Grillo, A.S., A.M. SantaMaria, M.D. Kafina, A.G. Cioffi, N.C. Huston, M. Han, Y.A. Seo, Y.Y. Yien, C. Nardone, A.V. Menon, J. Fan, D.C. Svoboda, J.B. Anderson, J.D. Hong, B.G. Nicolau, K. Subedi, A.A. Gewirth, M. Wessling-Resnick, J. Kim, B.H. Paw, and M.D. Burke. (2017). Restored iron transport by a small molecule promotes absorption and hemoglobinization in animals. Science 356: 608-616.
Guellec, J., A. Elbahnsi, M. Le Tertre, K. Uguen, I. Gourlaouen, C. Férec, C. Ka, I. Callebaut, and G. Le Gac. (2019). Molecular model of the ferroportin intracellular gate and implications for the human iron transport cycle and hemochromatosis type 4A. FASEB J. 33: 14625-14635.
Juneja, P., N. Rashid, F. Abul Qais, S. Tanwar, I. Sultan, F. Ahmad, and S.U. Rehman. (2024). Alternative splicing generates a novel ferroportin isoform with a shorter C-terminal and an intact iron- and hepcidin-binding property. IUBMB Life 76: 523-533.
Ka, C., J. Guellec, X. Pepermans, C. Kannengiesser, C. Ged, W. Wuyts, D. Cassiman, V. de Ledinghen, B. Varet, C. de Kerguenec, C. Oudin, I. Gourlaouen, T. Lefebvre, C. Férec, I. Callebaut, and G. Le Gac. (2018). The R178Q mutation is a recurrent cause of hemochromatosis and is associated with a novel pathogenic mechanism. Haematologica 103: 1796-1805.
Knutson, M.D., M. Oukka, L.M. Koss, F. Aydemir, and M. Wessling-Resnick. (2005). Iron release from macrophages after erythrophagocytosis is up-regulated by ferroportin 1 overexpression and down-regulated by hepcidin. Proc. Natl. Acad. Sci. USA 102: 1324-1328.
Le Gac G., Ka C., Joubrel R., Gourlaouen I., Lehn P., Mornon JP., Ferec C. and Callebaut I. (2013). Structure-function analysis of the human ferroportin iron exporter (SLC40A1): effect of hemochromatosis type 4 disease mutations and identification of critical residues. Hum Mutat. 34(10):1371-80.
Le Tertre, M., A. Elbahnsi, C. Ka, I. Callebaut, and G. Le Gac. (2021). Insights into the Role of the Discontinuous TM7 Helix of Human Ferroportin through the Prism of the Asp325 Residue. Int J Mol Sci 22:.
Madejczyk, M.S. and N. Ballatori. (2012). The iron transporter ferroportin can also function as a manganese exporter. Biochim. Biophys. Acta. 1818: 651-657.
McKie, A.T. and D.J. Barlow. (2004). The SLC40 basolateral iron transporter family (IREG1/ferroportin/MTP1). Pflugers Arch. 447: 801-806.
McKie, A.T., P. Marciani, A. Rolfs, K. Brennan, K. Wehr, D. Barrow, S. Miret, A. Bomford, T.J. Peters, F. Farzaneh, M.A. Hediger, M.W. Hentze, and R. J. Simpson. (2000). A novel duodenal iron-regulated transporter, IREG1, implicated in the basolateral transfer of iron to the circulation. Mol. Cell. 5: 299-309.
Morrissey, J., I.R. Baxter, J. Lee, L. Li, B. Lahner, N. Grotz, J. Kaplan, D.E. Salt, and M.L. Guerinot. (2009). The ferroportin metal efflux proteins function in iron and cobalt homeostasis in Arabidopsis. Plant Cell 21: 3326-3338.
Núñez, M.T., V. Tapia, A. Rojas, P. Aguirre, F. Gómez, and F. Nualart. (2010). Iron supply determines apical/basolateral membrane distribution of intestinal iron transporters DMT1 and ferroportin 1. Am. J. Physiol. Cell Physiol. 298: C477-485.
Rafiee, A., S. Fatemi, S. Jamili, S. Ajdari, F. Riazi-Rad, A. Memarnejadian, and M. Alimohammadian. (2012). Cloning, Expression and Characterization of Zebra Fish Ferroportin in Hek 293T Cell Line. Iran J Public Health 41: 79-86.
Rescigno, M. (2020). The "iron will" of the gut. Science 368: 129-130.
Taniguchi, R., H.E. Kato, J. Font, C.N. Deshpande, M. Wada, K. Ito, R. Ishitani, M. Jormakka, and O. Nureki. (2015). Outward- and inward-facing structures of a putative bacterial transition-metal transporter with homology to ferroportin. Nat Commun 6: 8545.
Tsuji, Y. (2020). Transmembrane protein western blotting: Impact of sample preparation on detection of SLC11A2 (DMT1) and SLC40A1 (ferroportin). PLoS One 15: e0235563.
Uguen, K., M. Le Tertre, D. Tchernitchko, A. Elbahnsi, S. Maestri, I. Gourlaouen, C. Férec, C. Ka, I. Callebaut, and G. Le Gac. (2024). The dual loss and gain of function of the FPN1 iron exporter results in the ferroportin disease phenotype. HGG Adv 5: 100335.
Wang, C., Y. Xiang, Y. Shao, and C. Li. (2024). Ferroptosis resists intracellular Vibrio splendidus AJ01 mediated by ferroportin in sea cucumber Apostichopus japonicus. Fish Shellfish Immunol 149: 109585.
Yang, F., X. Liu, M. Quinones, P.C. Melby, A. Ghio, and D.J. Haile. (2002). Regulation of reticuloendothelial iron transporter MTP1 (Slc11a3) by inflammation. J. Biol. Chem. 277: 39786-39791.
Yeh, K.Y., M. Yeh, and J. Glass. (2011). Interactions between ferroportin and hephaestin in rat enterocytes are reduced after iron ingestion. Gastroenterology 141: 292-9, 299.e1.
Zhou, F., Y. Yang, S. Chemuru, W. Cui, S. Liu, M. Gross, and W. Li. (2021). Footprinting Mass Spectrometry of Membrane Proteins: Ferroportin Reconstituted in Saposin A Picodiscs. Anal Chem 93: 11370-11378.
Examples:
TC#	Name	Organismal Type	Example
2.A.100.1.1	The iron exporter Ferroportin1 (Fnp1 or IREG1)	Animals, Plants	Ferroportin (IREG1) of Mus musculus

2.A.100.1.2	*The probable chloroplast Fe transporter, Mar1 (Conte et al., 2009)*	Plants	*Mar1 of Arabidopsis thaliana* (Q8W4E7)**

2.A.100.1.3	*Ferroportin1 or Iron-regulated protein1, 9FPN1, IREG1, ATIREG1; exports Fe²⁺, Co²⁺ and Ni²⁺ (Morrissey et al., 2009)*	Plants	*FPN1 of Arabidopsis thaliana* (O80905)**

2.A.100.1.4	Solute carrier family 40 member 1 (Ferroportin-1; FPN1, SLC40A1, FPN, IREG1, SLC11A3)) (Iron-regulated transporter 1). Transports iron, cobalt, zinc and manganese, magnesium, and maybe copper (Madejczyk and Ballatori 2012). Regulated by its inhibitor, the processed liver antimicrobial peptide, hepcidin (TC# 8.A.37.1.2). Tryptophan 42, a hemochromatosis type 4 disease residue, plays a role in iron export and iron homeostasis as well as hepcidin binding (Le Gac et al. 2013). This protein has been modeled using the MSF EmrD of E. coli (TC# 2.A.1.2.9) (Le Gac et al. 2013). Defects can be corrected by adding the small molecule, hinokitiol (Cioffi et al. 2015; Grillo et al. 2017). The R178Q mutation is a recurrent cause of hemochromatosis and is associated with a novel pathogenic mechanism (Ka et al. 2018). The function of the "gating residues" in the mechanism of iron export have been modeled and studied (Guellec et al. 2019). Optimal conditions for Western blotting for this and other proteins requires that the sample not be boiled (Tsuji 2020). Ferroptosis resists intracellular Vibrio splendidus AJ01 mediated by ferroportin in sea cucumber Apostichopus japonicus (Wang et al. 2024). Alternative splicing generates a novel ferroportin isoform with a shorter C-terminal and intact iron- and hepcidin-binding properties (Juneja et al. 2024). Dual loss and gain of function of the FPN1 iron exporter results in the ferroportin disease phenotype (Uguen et al. 2024).	Animals	FPN1 or SLC40A1 of Homo sapiens

2.A.100.1.5	Ferroportin of 565 aas and 12 TMSs.	*Ferroportin of Chlorella variabilis* (Green alga)**	*Fpn of Chlorella variabilis* (Green alga)**

2.A.100.1.6	Uncharacterized ferroportin homolog of 560 aas and 14 TMSs, with two extra TMSs between the two 6 TMS repeat units.		UP of Peronospora effusa

2.A.100.1.7	Ferroportin1 (Fpn1) of 562 aas and 12 TMSs (Rafiee et al. 2012). Missense mutations in Fpn1, an intestinal and macrophage iron exporter, have been identified between TMSs 3 and 4 in the zebrafish anemia mutant weissherbst (weh(Tp85c-/-)) and in patients with type 4 hemochromatosis. Thus, ferroportin1 is required for normal iron cycling in both humans and zebrafish (Fraenkel et al. 2005).		*Fpn of Danio rerio* (zebrafish)**

Examples:
TC#	Name	Organismal Type	Example
2.A.100.2.1	Ferroportin of 440 aas and 12 TMSs. Transports Fe²⁺, Co²⁺, Mn²⁺ and Ni²⁺. The 3-d structures in both the inward and outward facing orientations have been determined, showing similarities to those of MFS permeases (Taniguchi et al. 2015). The Fpn family is a member of the MFS. Fpn-mediated iron efflux is stimulated by extracellular Ca²⁺ in the physiological range, even though Ca²⁺ is not transported. Deshpande et al. 2018 determined the crystal structure of Ca²⁺-bound BbFpn (TC# 2.A.100.2.1), and found that Ca²⁺ is a cofactor that facilitates a conformational change critical to the transport cycle. They also identified a substrate pocket accommodating a divalent transition metal complexed with a chelator. These findings support a model of iron export by Fpn and suggest a link between plasma calcium and iron homeostasis (Deshpande et al. 2018).		Ferroportin of Bdellovibrio bacteriovorus

2.A.100.2.2	Uncharacterized Ferroporin homologue of 592 aas and 12 putative TMSs.		UP of Acytostelium subglobosum