Expression and structural and functional properties of human ferritin L-chain from Escherichia coli
The human ferritin L-chain cDNA was cloned into a vector for overproduction in Escherichia coli, under the regulation of a lambda promoter. The plasmid obtained contains the full L-chain coding region modified at the first two codons. It is able to direct the synthesis of the L-chain which can constitute up to 15% of the total soluble protein of bacterial extract. The L-chains assemble to form a ferritin homopolymer with electrophoretic mobility, molecular weight, thermal stability, spectroscopic, and immunological properties analogous to natural ferritin from human liver (95% L-chain). This recombinant L-ferritin is able to incorporate and retain iron in solution at physiological pH values. At variance with the H-ferritin, the L form does not uptake iron at acidic pH values and does not show detectable ferroxidase activity. It is concluded that ferritin L-chain lacks the ferroxidase site present in the H-chain and that the two chains may have specialized functions in intracellular iron metabolism.
Acidic isoferritins have been identified as leukemia-associated inhibitory activity (LIA), which suppresses colony and cluster formation of colony-forming unit-granulocyte macrophages from normal donors but not from patients with leukemia. LIA was detected in all ferritin preparations tested, including ferritin isolated from normal heart, spleen, liver, and placental tissues, and from the spleens of patients with chronic myelogenous leukemia and Hodgkin's disease. Purified preparations of LIA were composed almost entirely of acidic isoferritins, as determined by immunoassay, radioimmunoassay, and isoelectric focusing. The inhibitory activity in the LIA and ferritin samples was inactivated by a battery of antisera specific for ferritin, including those prepared against acidic isoferritins from normal heart and spleen tissues from patients with Hodgkin's disease, and those previously absorbed with basic isoferritins. Antisera absorbed with acidic isoferritins did not inactivate the inhibitory activity. Separation of LIA and chronic myelogenous leukemia and normal spleen ferritin by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and isoelectric focusing confirmed that the regions of peak inhibitory activity corresponded in each to an apparent molecular weight of approximately 550,000 and to a pI value of 4.7. Similar physicochemical characteristics included inactivation by methods that dissociate ferritin molecules into subunits and by treatment with trypsin, chymotrypsin, pronase, and periodate. The purified preparations were extremely stable to heat treatment. The glycoprotein nature of the inhibitory activity was substantiated because it bound to concanavalin A-Sepharose and was eluted off by alpha-methyl mannose. Inhibitory activity of the activity of the acidic isoferritins was detected at concentrations as low as 10(-17)-10(-19) M and iron saturation did not appear to be necessary for its action. These results implicate acidic isoferritins in the regulation of normal myelopoiesis and suggest a role for them in the progression of leukemia.
Mononuclear cells from peripheral blood of normal humans, unselected spleen cells from patients with Hodgkin's disease, and selected T and non-T lymphoid cells from normal peripheral blood and from the spleens of Hodgkin's disease patients were examined for de novo synthesis and secretion of ferritin. After precipitation of labeled lysates and supernatants from unseparated and selected T cells with antiserum to human liver ferritin, two bands were visible on sodium dodecyl sulfate-polyacrylimide gel analysis. The two bands were detected in molecular weight regions 19,000 and 21,000, which are thought to represent the L and H subunits of the ferritin molecule, respectively. The slower band (subunit H) was more radioactive than the faster band (subunit L). The H subunit is found in greater amounts in the serum of some tumor patients, but its cellular origin has not been established. The present findings indicate that cells of the immune system contribute to the synthesis and secretion of a ferritin molecule with a high proportion of H subunits.
Structure of human ferritin light subunit messenger RNA: comparison with heavy subunit message and functional implications.
Ferritin has a protein shell of 5 x 106 Da consisting of 24 subunits of two types, a heavier (H) chain of 21,000 Da and a lighter (L) chain of 19,000 Da. A cDNA clone of the messenger for the L subunit has been isolated from a human monocyte-like leukemia cell line. The clone contains an open reading frame of 522 nucleotides coding for an amino acid sequence matching 97% of the published sequence of human liver ferritin L subunit determined by sequenator, but it corresponds to only 55% of the reported amino acid sequence of a human liver H-subunit clone. Nevertheless, computer analysis of the subunit conformations predicted from the open reading frames of the L and H clones shows that most of the amino acid differences are conservative and would allow both subunits to form the five a-helices and 13-turns established by x-ray crystallography for horse spleen ferritin subunits. This suggests that L and H subunits are structurally interchangeable in forming an apoferritin shell. The 5' untranslated region of our human ferritin L clone has considerable homology with that of the rat liver ferritin L clone in the region immediately upstream from the initiator codon, notably showing an identical sequence of 10 nucleotides at the same position in both subunit clones that may participate in regulating the known activation of ferritin mRNA after iron administration. Extensive homology, including several blocks of nucleotides, was identified between the 3' untranslated regions ofthe human and rat L clones. The common structural features of the H and L subunits lead us to conclude that they have diverged from a single ancestral gene.Ferritin, an iron-storage protein found in bacteria, molds, plants, and animals (1), consists of a protein shell with channels through which ferrous iron enters the cavity and is stored after oxidation to ferric iron. The protein shell is -5 x 10' Da and consists of 24 subunits of two species, one of 19,000 Da (light, L subunit) and the other of 21,000 Da (heavy, H subunit). In individual cells, the ferritin shell contains the two subunits in a range of proportions (isoferritins) that varies from tissue to tissue and with iron load (2). The amino acid sequences of the L subunit of human liver (3) and spleen (4) and of horse spleen and liver (5) have been obtained by direct protein sequencing, while those of the L subunit of rat liver (6) and the H subunit of human liver (7) have been deduced from cDNA preparations. Here, we describe the structure of a clone isolated from a human monocyte-like leukemic cell line encoding the L subunit of human ferritin.There are several biological reasons for acquiring more detailed knowledge of the structural features of the ferritin genome in several species. First, translation of ferritin mRNA appears to be regulated in rat liver (8) and in bullfrog erythrocytes (9) by a mechanism in which ferritin messenger present in the cytoplasm in latent form is activated by iron to synthesize ferritin subunits. Sequences of ferritin mRNAs conserved during evoluti...
The recent identification of a leukemia-associated inhibitory activity (LIA) against granulocyte-macrophage progenitor cells (CFU-GM) as acidic isoferritins has now led to detection of this activity in normal bone marrow and blood cells. Detection of this activity depends on stimulation of CFU-GM by granulocyte-macrophage colony stimulatory factors (GM-CSF), and some conditioned media (CM) sources of GM-CSF (human placental and monocyte, mouse macrophage and WEHI-3) contained low levels of acidic isoferritin that lowered colony formation. Inactivation or removal of this activity increased the stimulatory capacity of the CM. CM depleted of acidic isoferritins or CM originally devoid of this activity (human GCT, 5637, Mo, lymphocytes: mouse L cells or pokeweed-mitogen-stimulated spleen cells) increased the sensitivity of the assay to detect acidic isoferritin inhibitory activity. This activity was selectively contained and released from normal monocytes and macrophages. Restriction of this activity to mononuclear phagocytes was substantiated, as only continuous cell lines of monocytes and macrophages or lines capable of induction to this lineage contained and released acidic isoferritin inhibitory activity. The cells of origin and target cells of action suggest that acidic isoferritin-inhibitory activity can be considered as a negative feedback regulator, at least in vitro.
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