Major Iron-binding Protein Research Articles

Rapamycin-induced autophagy plays a pro-survival role by enhancing up-regulation of intracellular ferritin expression in acute lymphoblastic leukemia.

Cell proliferation was detected by 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide assay in ALL cell lines of CEM-C1and CEM-C7. Western Blot analysis was performed to test protein expressions. Inhibition of mTOR by rapamycin could reverse glucocorticoid resistance in CEM-C1cells, and also induce autophagy in these cells by up-regulation of LC3-IIand Beclin-1 expressions. This autophagy played a pro-survival role since its inhibition by 6-amino-3-methylpurine or chroloquine could enhance rapamycin-induced cell death. Rapamycin increased the expression of intracellular ferritin, and this effect could be totally blocked by 6-amino-3-methylpurine and chroloquine, suggesting that the protective role of autophagy might be mediated through up-regulation of ferritin, the major iron-binding stress protein. Ciclopirox olamine, an iron chelator, could enhance rapamycin's anti-leukemia effect by down-regulation of intracellular ferritin expression. All these findings would suggest that rapamycin-induced autophagy plays a pro-survival role in leukemia cells and this effect might be mediated by up-regulation of intracellular ferritin expression. We hypothesize that the combination of mTOR pathway inhibitors and autophagy inhibition is rational and would induce strong anti-leukemia effects in ALL.

Ameliorative Role of Lactoferrin on Osteoporosis Caused by Glucocorticoids

Lactoferrin is derived from its past classification as a major iron-binding protein in milk,Which was in bovine milk. Osteoporosis is a major disease affecting human bone. Which is caused by endocrinological disorders and drugs Glucocorticoids – induced osteoporosis is the most common form of secondary osteoporosis.The current study was aimed to study the curative role of natural substances (lactoferrin) on the osteoporosis caused by glucocorticoids (prednisone) and comparing its curative effect with sodium alendronate the common therapy for osteoporosis. Our experiment included 8 groups in each group 10 adult’s albino rats 4 groups male or the other groups are female. First group (normal females) and fifth group (normal males) were given saline for two months. Second group (control females) and sixth group (control males) were given prednisone orally (25mg/kg b. w.) day after day for two months. Third group (treated females) and seventh group(treated males)were given(25mg/ kg b.w.) day after day for two months and then lactoferrin (0.85 mg/kg body weight) daily for two months. Fourth group (treated females) and eighth group(treated males) were given (25mg/ kg b.w.) day after day for two months and then sodium alendronate (300 μg/kg b.w.) once weekly for two months. After treatment, blood samples were collected for estimating calcium, phosphorous, PTH and testosterone levels in serum. Right femur bones were removed for determining the density, calcium and phosphorous content. The results indicated that lactoferrin and prednisone were increased serum calcium and PTH levels P < (0.05), in males and females animals and decreased serum phosphorous for the two sexes, but for testosterone there was a non-significant decrease for female animals and a significant decrease for male animals. Administration of lactoferrin was ameliorated the disturbances of bone. The result suggests that lactoferrin may improve prednisone -induced osteoporosis.

Transferrin in fishes: A review article

Transferrin is a single monomeric glycoprotein of molecular weight of 80 kDa that transports iron involved in many metabolic processes amongst the sites of absorption, storage and utilization, hence considered as the major iron binding protein in the plasma of vertebrate species. In this study, transferrin structure, synthesis, receptor and the mechanism of cellular uptake of iron from transferrin have been reviewed. Besides, the major biological functions of transferrin and the different forms of it (polymorphisms) have been indicated.

Silkworm ferritin 1 heavy chain homolog is involved in defense against bacterial infection through regulation of haemolymph iron homeostasis

Iron functions as a nutrient and a potential toxin in all organisms. It plays a key role in the interaction between microbes and their hosts as well. Microbial infection disrupts iron homeostasis in the host; meanwhile the host endeavors to keep the homeostasis through iron transport and storage. Transferrins and ferritins are the major iron-binding proteins that affect iron distribution in insects. In this study, we investigated a possible involvement of Bombyx mori ferritin 1 (BmFer1) heavy chain homolog in the defense against bacterial infection in the silkworm larvae. The BmFer1 mRNA abundance was up-regulated in hemocytes, but not in fat body, after Pseudomonas aeruginosa or Staphylococcus aureus infection. The infection resulted in elevated iron levels in the hemolymph. Injection of recombinant BmFer1 protein into hemocoel reduced the plasma iron level after infection, limited the bacterial growth in the hemolymph, and resulted in a lower mortality caused by infection. Our study indicated that B. mori ferritin-1 may restrict iron access of the invading bacteria to block their growth as a defense strategy.

PO-0198 Ferritin And Serum Iron In Paediatric Febrile Illness

<h3>Introduction</h3> Ferritin is the major intracellular iron binding protein in the body. Serum ferritin is an inflammatory marker. Iron sequestration is one of the innate immune responses to infection. The goal of this research was to investigate the role of serum ferritin and serum iron as clinically useful markers of infection in the paediatric emergency department. <h3>Methods</h3> Multiple inflammatory markers, including C-reactive protein, procalcitonin, and serum ferritin, and other iron studies were measured in 37 children, from 3 months through 8 years of age, presenting to the emergency department with temperature of ≥39 degrees Celsius, and 38 patients in the same age group with non-febrile illness (controls). Patients with chronic inflammatory or rheumatologic conditions and those with renal or hepatic failure were excluded. <h3>Results</h3> Mean serum ferritin, and ferritin/iron ratio were significantly higher among febrile children when compared to controls. Mean serum iron levels were significantly lower among febrile patients and in the subgroup of children who had bacterial infections when compared with children who had viral infections and those who had a non-infectious illness. <h3>Conclusion</h3> Serum iron and ferritin/iron ratio may be clinically useful markers for the differentiation of bacterial from viral infection in the emergency department. Further studies are needed to confirm our findings and to further explore the role of iron metabolism in paediatric infections.

Are extrinsic black stains of teeth iron-saturated bovine lactoferrin and a sign of iron deficient anemia or iron overload?

Extrinsic black stains on teeth are shown to have a relation with a low incidence of caries and are made of a ferric compound. Whole composition and why those stains are formed are not fully understood. Studies have shown low incidence of caries in individuals eating cheese. Lactoferrin is the major iron-binding protein, constituent of milk, stays almost intact during cheese making and has antibacterial activity against dental cavity-inducing Streptococcus mutans. Lactoferrin has a high affinity for iron and whenever it is present it will bind iron and release it only in values of pH<4. In a small survey that I made in dental practice, patients (patients did not report taking any medication; had no frequent gingival bleeding) that had extrinsic black stains on teeth eat >50g of cheese per day and a good number of them, in addition to cheese, drink one cup of milk per day. Cheese stays much longer in contact with tooth surface than does’ milk and bovine lactoferrin has four glycan chains that may contribute to a better adherence. Extrinsic black stains are made of a ferric compound, and people that eat good amounts of cheese (where lactoferrin plays a central role) show to have black stains. Iron must be in sufficient amounts in saliva so that lactoferrin can bind it and as a result making the black stains appear. In iron deficient anemia and in iron overload the concentration of iron present in saliva is much higher than in individuals with no anemia. In conclusion, extrinsic black stains of teeth may be iron-saturated bovine lactoferrin and a sign of iron deficient anemia or iron overload if no iron supplements are taken or individuals have no frequent gingival bleeding.

Apo‐ and holo‐lactoferrin are both internalized by lactoferrin receptor via clathrin‐mediated endocytosis but differentially affect ERK‐signaling and cell proliferation in caco‐2 cells

Lactoferrin (Lf) is a major iron-binding and multi-functional protein in exocrine fluids such as breast milk and mucosal secretions. The functions of Lf appear dependent upon the iron saturation of the Lf protein and are postulated to be mediated through Lf internalization by a Lf receptor (LfR). However, mechanisms by which LfR mediates Lf internalization in enterocytes are unknown. We now demonstrate that a LfR previously cloned from the small intestine mediates Lf endocytosis in a human enterocyte model (Caco-2 cells). LfR was detected at the plasma membrane by cell surface biotinylation; both apo-Lf and holo-Lf uptake were significantly inhibited in cells transfected with LfR siRNA. Treatments of hypertonic sucrose and clathrin siRNA and co-immunoprecipitation of LfR with clathrin adaptor AP2 indicate that LfR regulates Lf endocytosis via clathrin-mediated endocytosis. Although both iron-free Lf (apo-Lf) and iron-saturated Lf (holo-Lf) enter Caco-2 cells via a similar mechanism and no significant differences were observed in the binding and uptake of apo- and holo-Lf in Caco-2 cells, apo-Lf but not holo-Lf stimulates proliferation of Caco-2 cells. Interestingly, apo-Lf stimulated extracellular signal-regulated mitogen-activated protein kinase (ERK) cascade to a significantly greater extent than holo-Lf and the apo-Lf induced proliferation was significantly inhibited by an ERK cascade inhibitor (U0126) and clathrin siRNA. Taken together, our data suggest that LfR is a major pathway through which Lf is taken up by enterocytes, which occurs independently of iron saturation through clathrin-mediated endocytosis. The differential effects of apo- and holo-Lf are not due to differences in cellular internalization mechanisms.

Evaluation of ferritin-overexpressing brain in newly developed transgenic mice

Aberrant expression of ferritin, a major iron-binding protein, has shown to be involved in neurodegenerative diseases. In this study, we generated transgenic (Tg) mice of human ferritin heavy chain (FTH) gene and investigated the effects of ferritin overexpression in FTH-Tg brain by 1H-MRI and 1H-MRS. The mice displayed no apparent neurological symptoms, and no specific morphological and T 2 alterations were found in the brain by MRI, and not even by histological studies. 1H-MRS, however, revealed that some metabolic markers were significantly altered in FTH-Tg brains compared to wild-type control brains, such as decreases in myo-inositol and glutamine, and an increase in lactate. Our present studies suggested that despite the absence of neurological, morphological, T 2, and histological signatures, brain metabolisms were significantly affected in FTH-Tg mice. This study also highlights the usefulness of 1H-MRS in the analysis of transgenic mouse models.

Plant-derived recombinant human serum transferrin demonstrates multiple functions

Human serum transferrin (hTf) is the major iron-binding protein in human plasma, having a vital role in iron transport. Additionally, hTf has many other uses including antimicrobial functions and growth factor effects on mammalian cell proliferation and differentiation. The multitask nature of hTf makes it highly valuable for different therapeutic and commercial applications. However, the success of hTf in these applications is critically dependent on the availability of high-quality hTf in large amounts. In this study, we have developed plants as a novel platform for the production of recombinant (r)hTf. We show here that transgenic plants are an efficient system for rhTf production, with a maximum accumulation of 0.25% total soluble protein (TSP) (or up to 33.5 microg/g fresh leaf weight). Furthermore, plant-derived rhTf retains many of the biological activities synonymous with native hTf. In particular, rhTf reversibly binds iron in vitro, exhibits bacteriostatic activity, supports cell proliferation in serum-free medium and can be internalized into mammalian cells in vitro. The success of this study validates the future application of plant rhTf in a variety of fields. Of particular interest is the use of plant rhTf as a novel carrier for cell-specific or oral delivery of protein/peptide drugs for the treatment of human diseases such as diabetes.To demonstrate this hypothesis, we have additionally expressed an hTf fusion protein containing glucagon-like peptide 1 (GLP-1) or its derivative in plants. Here, we show that plant-derived hTf-GLP-1 fusion proteins retain the ability to be internalized by mammalian cells when added to culture medium in vitro.

Protective Effects of Lactoferrin against Intestinal Mucosal Damage Induced by Lipopolysaccharide in Human Intestinal Caco-2 Cells

Indirect evidence suggests that lactoferrin (Lf), a major iron-binding protein in human milk, induces enterocyte growth and proliferation, depending on its concentration and affects the function and permeability of the intestinal mucosa. The bacterial endotoxin (lipopolysaccharide, LPS) is known to cause mucosal hyperpermeability in vivo. However, protective effects of Lf against LPS-mediated intestinal mucosal damage and barrier function in epithelial cells are not yet fully clarified. The aim of this study was to investigate whether Lf can reduce the cellular injury and alter epithelial hyperpermeability caused by LPS in human intestinal Caco-2 cells. When cell viability was measured by a WST-1 assay (tetrazolium salt-based assay), the protective effects against LPS-induced damage to Caco-2 cells were observed at doses of 800 and 1000 microg/ml Lf. The barrier function of Caco-2 monolayer tight junctions was assessed by measuring transepithelial electrical resistance (TEER) and permeability of FITC-labeled dextran 4000 (FD-4). The treatment of Caco-2 cells with Lf at doses of 400 and 1000 microg/ml significantly increased TEER as compared to treatment with LPS alone for 2 h (p<0.05). Further, at doses of 400 and 1000 microg/ml, Lf inhibited the enhancement of LPS-mediated permeability in Caco-2 cell monolayer. The results of this study suggest that Lf may have protective effects against LPS-mediated intestinal mucosal damage and impairment of barrier function in intestinal epithelial cells.

The effects of frataxin silencing in HeLa cells are rescued by the expression of human mitochondrial ferritin

Frataxin is a ubiquitous mitochondrial iron-binding protein involved in the biosynthesis of Fe/S clusters and heme. Its deficiency causes Friedreich's ataxia, a severe neurodegenerative disease. Mitochondrial ferritin is another major iron-binding protein, abundant in the testis and in sideroblasts from patients with sideroblastic anemia. We previously showed that its expression rescued the defects caused by frataxin deficiency in the yeast. To verify if this occurs also in mammals, we silenced frataxin in HeLa cells. This caused a reduction of growth, inhibition of the activity of aconitase and superoxide dismutase-2 and reduction of cytosolic ferritins without alteration of mitochondrial iron content. None of these effects were evident when silencing was done in cells expressing mitochondrial ferritin. These data indicate that frataxin has some roles in controlling the balance between different mitochondrial iron pools that are partially in common with those of mitochondrial ferritin.

Effects of iron limitation on the expression of metabolic genes in the marine cyanobacterium Trichodesmium erythraeum IMS101

Iron deficiency in axenic cultures of Trichodesmium erythraeum IMS101 led to significant declines in both nitrogen fixation rates and photochemical energy conversion efficiency, accompanied by downregulation of genes encoding the major iron-binding proteins, including psbA and psbE of photosystem II, psaA and psaC of photosystem I, petB and petC of the cytochrome b(6)f complex, and nifH. However, the iron-starved cultures remained viable and expression of the metalloprotein genes was partially or fully restored within 3 days following the addition of iron. Both physiological and molecular responses revealed that expression and synthesis of the nitrogen fixation and photosynthetic machinery follow the hierarchy of iron demand; that is, nitrogen fixation was far more susceptible to iron limitation than photosynthesis. Consequently, the nifH transcript exhibited a 1-2 day shorter half-life and two to three times faster degradation rate than that of the photosynthetic genes. Our results suggest that the changes in gene expression are related to the redox state in the shared photosynthetic/respiratory pathway which, when faced with short-term iron deficiency, signals Trichodesmium to selectively sacrifice nitrogen fixation to conserve iron for photosynthetic and respiratory electron transport. The observed functional and compositional alterations represent the compromises in gene expression and acclimation capacity between two basic metabolic pathways competing for iron when it is limiting.

Lactoferrin iron levels are reduced in saliva of patients with localized aggressive periodontitis.

Actinobacillus actinomycetemcomitans (Aa) is associated with localized aggressive periodontal disease in juveniles (LAgP). Lactoferrin (LF) is an iron-binding salivary protein that has been shown to kill Aa in its iron-free form (apo) and reduce binding to host cells in its iron-saturated form (halo). However, recent in vitro studies show that LF does not kill clinical isolates of Aa, and LF with reduced levels of bound iron does not interfere with its attachment. These findings suggest that colonization of Aa may occur more readily in an environment containing LF with low iron levels. The purpose of this study was to examine the relationship of LF iron levels in saliva of LAgP patients as compared to their age-, gender-, and race-matched controls. Whole and parotid saliva was collected from LAgP patients and matched controls. Micrograms of LF/mg of protein as well as nanograms of iron/micrograms of LF were determined. Iron binding was determined in parotid saliva by addition of nonlabeled and 59Fe labeled iron. LAgP patients' whole saliva had higher LF levels than controls, but their LF contained less iron (P < or =0.005). No iron was found in LF from parotid saliva in either group. When iron was added to parotid saliva, the LAgP saliva bound 20 to 30 times less iron than controls (P< or =0.001). Finally, LF was identified as the major iron-binding protein in parotid saliva by 59Fe autoradiography and Western blotting. This study shows that the level of bound iron in LF is significantly reduced in LAgP patients compared to controls. These data suggest that LF from LAgP patients has a reduced capacity to bind iron and that LF iron levels may play an important role in Aa-induced LAgP.

Effect of transferrin polymorphism on the metabolism of vitamin C in Zimbabwean adults

Transferrin is the major iron binding protein in human plasma. In black persons, the transferrin CD phenotype has been associated with alterations in certain markers of iron status. We studied vitamin C status in a Zimbabwean population according to transferrin phenotype because vitamin C metabolism is influenced by iron-driven oxidative stress. The study population consisted of 150 black African adults, 90 of whom were at risk of iron overload on the basis of high dietary iron content in the form of traditional beer. Transferrin phenotypes, indirect measures of iron status, and leukocyte ascorbic acid concentrations were determined. The in vitro rate of L-ascorbic acid depletion in sera from different transferrin phenotypes was investigated. The transferrin phenotype frequencies of transferrin CC and CD were 0.893 and 0.107, respectively. The iron status of transferrin CC and CD subjects was similar. After adjustment for traditional beer consumption, baseline leukocyte vitamin C concentrations were significantly higher in 16 transferrin CD subjects ( +/- SE: 2.10 +/- 0.34 and 2.61 +/- 0.28 fmol/leukocyte in men and women, respectively) than in 134 transferrin CC subjects ( +/- SE: 1.65 +/- 0.11 and 1.99 +/- 0.11 fmol/leukocyte in men and women, respectively; P = 0.024). Oral administration of ascorbic acid (2.0 g every 24 h for 48 h) led to slower rises in leukocyte vitamin C concentrations in subjects with the transferrin CD phenotype than in subjects with the transferrin CC phenotype (P = 0.028). After in vitro supplementation of serum with 570 micromol vitamin C/L, the rate of L-ascorbic acid depletion was significantly lower in subjects of a transferrin CD phenotype than in subjects with the transferrin CC phenotype. Transferrin polymorphism may affect vitamin C status in blacks.

Molecular cloning and functional expression of a human intestinal lactoferrin receptor.

Lactoferrin (Lf), a major iron-binding protein in human milk, has been suggested to have multiple biological roles such as facilitating iron absorption, modulating the immune system, embryonic development, and cell proliferation. Our previous binding studies suggested the presence of a specific receptor for Lf (LfR) in the small intestine of newborn infants, which may facilitate iron absorption. We here report the cloning and the functional expression of the human intestinal LfR and the evidence of its involvement in iron metabolism. The entire coding region of the LfR cDNA was cloned by PCR based on amino acid sequences of the purified native LfR (nLfR). The recombinant LfR (rLfR) was then expressed in a baculovirus-insect cell system and purified by immobilized human Lf (hLf) affinity chromatography where binding of hLf to the rLfR was partially Ca(2+) dependent. The apparent molecular mass was 136 kDa under nonreducing conditions and 34 kDa under reducing conditions. 125I-hLf bound to the rLfR with an apparent K(d) of approximately 360 nM. These biochemical properties of the rLfR are similar to those of the nLfR. RT-PCR revealed that the gene was expressed at high levels in fetal small intestine and in adult heart and at lower levels in Caco-2 cells. PI-PLC treatment of Caco-2 cells indicated that the LfR is GPI anchored. In Caco-2 cells transfected with the LfR gene, 125I-hLf binding and 59Fe-hLf uptake were increased by 1.7 and 3.4 times, respectively, compared to those in mock-transfected cells. Our findings demonstrate the presence of a unique receptor-mediated mechanism for nutrient uptake by the newborn.

Coordinate transcriptional and translational regulation of ferritin in response to oxidative stress.

The global increase in transcription of cytoprotective genes induced in response to oxidative challenge has been termed the antioxidant response. Ferritin serves as the major iron-binding protein in nonhematopoietic tissues, limiting the catalytic availability of iron for participation in oxygen radical generation. Here we demonstrate that ferritin is a participant in the antioxidant response through a genetically defined electrophile response element (EpRE). The EpRE of ferritin H identified in this report exhibits sequence similarity to EpRE motifs found in antioxidant response genes such as those encoding NAD(P)H:quinone reductase, glutathione S-transferase, and heme oxygenase. However, the EpRE of ferritin H is unusual in structure, comprising two bidirectional motifs arranged in opposing directions on complementary DNA strands. In addition to EpRE-mediated transcriptional activation, we demonstrate that ferritin is subject to time-dependent translational control through regulation of iron-regulatory proteins (IRP). Although IRP-1 is initially activated to its RNA binding (ferritin-repressing) state by oxidants, it rapidly returns to its basal state. This permits the translation of newly synthesized ferritin transcripts and ultimately leads to increased levels of ferritin protein synthesis following oxidant exposure. Taken together, these results clarify the complex transcriptional and translational regulatory mechanisms that contribute to ferritin regulation in response to prooxidant stress and establish a role for ferritin in the antioxidant response.

Characteristic transport of lactoferrin from the intestinal lumen into the bile via the blood in piglets

Lactoferrin is a major iron-binding protein in milk from several species, such as humans, monkeys, mice and sows. Using neonatal and weaner piglets, the characteristic transfer of lactoferrin from intestinal lumen into bile via the circulation was investigated. Bovine lactoferrin (1 or 3 g/kg body weight) was infused into the stomach through a polyethylene tube or into the duodenum through a duodenal catheter over 5 min. Peripheral blood and bile samples were collected after the infusion. Lactoferrin absorbed into plasma and bile were assayed quantitatively by double-antibody enzyme-linked immunosorbent assay, and homogeneity of bovine lactoferrin in plasma and bile was identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting methods. Morphological investigation was carried out according to the peroxidase anti-peroxidase method. Following oral administration in neonatal pigs, bovine lactoferrin appeared in the blood circulation and reached a peak level after 2 h. It was confirmed immunohistochemically that lactoferrin was transported by endocytosis via the epithelial cells. Lactoferrin absorbed into the blood was also detected in the bile and reached a peak value 12 h after oral administration. Transportation of lactoferrin from the intestinal lumen into the bile via the bloodstream was also observed in weaner piglets. Lactoferrin transported into plasma and bile was confirmed to be the same substance as administrated lactoferrin by electrophoresis and immunoblotting methods. Lactoferrin transported into bile was re-absorbed into the blood in neonatal pigs. These results demonstrate that lactoferrin contained in milk is transported into the circulation from the intestinal lumen and excreted into the bile, suggesting the possibility of entero-hepatic circulation of lactoferrin in neonatal pigs.

Fur and iron transport proteins in the Brazilian purpuric fever clone of Haemophilus influenzae biogroup aegyptius.

The Brazilian purpuric fever (BPF) clone of Haemophilus influenzae biogroup aegyptius causes a fatal septicaemic disease, resembling fulminant meningococcal sepsis, in children. When isolate F3031 was grown under iron-limiting conditions, the presence of several iron-regulated proteins of 38-110 kDa was revealed by electrophoretic analysis and a Fur homologue was shown by immunoblotting. Dot-blot assays and immunoblotting indicated that BPF cells bound human transferrin and contained transferrin-binding proteins in the outer membrane. However, the binding activity and the biosynthesis of these proteins were detected even under iron-rich conditions. Immunoblot analysis demonstrated the presence of a periplasmic protein related to the ferric iron-binding protein A (FbpA), the major iron-binding protein described in Neisseria spp. However, the FbpA homologue in strain F3031 was constitutively expressed and was smaller than the periplasmic protein detected in H. influenzae type b strain Eagan. The periplasm of strain F3031 also contained a protein related to the Streptococcus parasanguis FimA protein which recently has been shown to be involved in iron acquisition in Yersinia pestis. Although the Eagan and F3031 FimA homologues had a similar mol. wt, of 31 kDa, the expression of the BPF fimA-like gene was not regulated by the iron concentration of the culture medium.

Regional distribution of iron, transferrin, ferritin, and oxidatively-modified proteins in young and aged Fischer 344 rat brains

Iron dysregulation in the brain is thought to contribute to the oxidative damage seen in neurodegenerative diseases including Alzheimer's disease and Parkinson's disease. A role for iron in the oxidative stress thought to contribute to normal ageing is less certain. To better characterize the role of iron in normal ageing, the concentrations of iron, transferrin, ferritin, and protein carbonyl groups are measured in nine separate regions of Fischer 344 rats. The largest (approximately 30%) age-related increases in brain iron concentration are seen in the temporal cortex, medial septum, and cerebellum. Ferritin concentration in these same brain regions increases 50 to 250% with age, while protein carbonyl concentration is only −27 to +4% of young rats. These results indicate that an increase in the major iron-binding protein ferritin compensates for any age-related increase in iron concentration, and suggest that the increased ferritin is cytoprotective, serving to prevent the accumulation of protein carbonyl groups (a principal product of metal-catalysed oxidation of proteins).

Complete sequence analysis of rat transferrin and expression of transferrin but not lactoferrin in the digestive glands

Rat milk and digestive juices contain transferrin but not lactoferrin, which is a major ironbinding protein in these secretions of human and mouse. To compare the structure of rat transferrin to that of transferrins and lactoferrins in other species, we isolated a cDNA clone containing the entire coding region of transferrin from rat liver and determined its sequence. The amino-acid sequence of rat transferrin had 69.8% identity with that of human transferrin and 48.8% identity with that of human lactoferrin. Rat transferrin, like other transferrins, had the potential N-linked glycosylation site only in the C-terminal domain, although lactoferrins characterized so far contained the glycosylation sites in both the N- and C-terminal domains. Southern and Northern analyses showed that there was the gene specifically hybridized with the mouse lactoferrin cDNA in rat genomic DNA, but only the transferrin mRNA was detected in mammary gland, submaxillary gland and pancreas of rat. These results suggest that the rat lactoferrin gene is silent in the mammary gland, and transferrin can serve as a functional substitute for lactoferrin in rat.