José A. Lebrón

Crystal Structure of the Hemochromatosis Protein HFE and Characterization of Its Interaction with Transferrin Receptor

HFE is an MHC-related protein that is mutated in the iron-overload disease hereditary hemochromatosis. HFE binds to transferrin receptor (TfR) and reduces its affinity for iron-loaded transferrin, implicating HFE in iron metabolism. The 2.6 A crystal structure of HFE reveals the locations of hemochromatosis mutations and a patch of histidines that could be involved in pH-dependent interactions. We also demonstrate that soluble TfR and HFE bind tightly at the basic pH of the cell surface, but not at the acidic pH of intracellular vesicles. TfR:HFE stoichiometry (2:1) differs from TfR:transferrin stoichiometry (2:2), implying a different mode of binding for HFE and transferrin to TfR, consistent with our demonstration that HFE, transferrin, and TfR form a ternary complex.

Crystal structure of the hereditary haemochromatosis protein HFE complexed with transferrin receptor.

HFE is related to major histocompatibility complex (MHC) class I proteins and is mutated in the iron-overload disease hereditary haemochromatosis. HFE binds to the transferrin receptor (TfR), a receptor by which cells acquire iron-loaded transferrin. The 2.8 Å crystal structure of a complex between the extracellular portions of HFE and TfR shows two HFE molecules which grasp each side of a twofold symmetric TfR dimer. On a cell membrane containing both proteins, HFE would ‘lie down’ parallel to the membrane, such that the HFE helices that delineate the counterpart of the MHC peptide-binding groove make extensive contacts with helices in the TfR dimerization domain. The structures of TfR alone and complexed with HFE differ in their domain arrangement and dimer interfaces, providing a mechanism for communicating binding events between TfR chains. The HFE–TfR complex suggests a binding site for transferrin on TfR and sheds light upon the function of HFE in regulating iron homeostasis.

Binding and uptake of H-ferritin are mediated by human transferrin receptor-1

Ferritin is a spherical molecule composed of 24 subunits of two types, ferritin H chain (FHC) and ferritin L chain (FLC). Ferritin stores iron within cells, but it also circulates and binds specifically and saturably to a variety of cell types. For most cell types, this binding can be mediated by ferritin composed only of FHC (HFt) but not by ferritin composed only of FLC (LFt), indicating that binding of ferritin to cells is mediated by FHC but not FLC. By using expression cloning, we identified human transferrin receptor-1 (TfR1) as an important receptor for HFt with little or no binding to LFt. In vitro, HFt can be precipitated by soluble TfR1, showing that this interaction is not dependent on other proteins. Binding of HFt to TfR1 is partially inhibited by diferric transferrin, but it is hindered little, if at all, by HFE. After binding of HFt to TfR1 on the cell surface, HFt enters both endosomes and lysosomes. TfR1 accounts for most, if not all, of the binding of HFt to mitogen-activated T and B cells, circulating reticulocytes, and all cell lines that we have studied. The demonstration that TfR1 can bind HFt as well as Tf raises the possibility that this dual receptor function may coordinate the processing and use of iron by these iron-binding molecules.

Tolerization of adult mice to immunodominant proteins before monoclonal antibody production

Generating monoclonal antibodies (mAbs) against one polypeptide chain of a heterodimeric protein can be difficult when the other chain is more immunogenic. To influence the immune response in favor of the less immunogenic protein, we rendered adult mice tolerant to the immunodominant protein using a procedure based on the phenomenon of high zone tolerance. We then immunized the tolerized mice with a heterodimeric protein containing the immunogenic protein and produced hybridomas in the usual way. Screening the hybridomas for reactivity against the immunodominant protein and against the heterodimer revealed that this tolerization procedure can result in an increase of hybridomas producing mAbs against the protein of interest by up to 90-fold. This method should be of general utility for the production of mAbs against weakly antigenic proteins in mixtures of antigens.

The Hereditary Hemochromatosis Gene and Iron Homeostasis

Hereditary hemochromatosis (HH) is an autosomal recessive disorder of iron metabolism and represents one of the most common inherited disorders in individuals of Northern European descent with an estimated carrier frequency between 1 in 8 and 1 in 10.1–3 In patients with HH, excessive iron deposition in a variety of organs leads to multiorgan dysfunction.4,5 The symptoms of HH are often similar to other diseases and for this reason, the diagnoses of HH is frequently not made until later in life. HH has commonly been identified with a combination of blood iron measurements and liver biopsy. It has been argued that early detection of the HH and a simple program of therapeutic phlebotomy would be of benefit in preventing the onset of this disease. With the advent of the gene cloning, it is now possible to detect HH with a DNA based test so that diagnosis can be made before the deleterious effects of excess iron are realized.