A new transferrin allele in sheep

Summary. An electrophoretic variant of sheep transferrin, TfL, has been described. Transferrin L has been shown to be controlled by a single codominant allele, TfL, at the Tf locus. Transferrin L is electrophoretically distinguishable from the very similar transferrin TfKCzech. The value of gradient polyacrylamide gel electrophoresis for transferrin phenotyping in sheep is discussed.     

Transferrin types and reproduction in sheep

Transferrin types were determined for flocks of Finnish Landrace, Clun Forest, Soay and Merino sheep and gene frequencies were calculated. Analysis of ratios of transferrin types in segregating matings of Finnish Landrace and Clun Forest revealed a significant excess of heterozygotes in matings of heterozygous rams with heterozygous and with homozygous ewes. In Finnish Landrace, matings of sheep homozygous for Tf ^c to those heterozygous for Tf ^C gave a significant excess of homozygous male lambs and heterozygous female lambs. Finnish Landrace ewes of transferrin type BD had smaller litters than ewes of other types.     

Transferrin receptor 2: a new molecule in iron metabolism

Transferrin receptor 1 (TfR1) which mediates uptake of transferrin-bound iron, is essential for life in mammals. Recently, a close homologue of human transferrin receptor 1 was cloned and called transferrin receptor 2 (TfR2). A similar molecule has been identified in the mouse. Human transferrin receptor 2 is 45% identical with transferrin receptor 1 in the extracellular domain, but contains no iron responsive element in its mRNA and is apparently not regulated by intracellular iron concentration nor by interaction with HFE. Transferrin receptor 2, like transferrin receptor 1, binds transferrin in a pH-dependent manner (but with 25 times lower affinity) and delivers iron to cells. However, transferrin receptor 2 distribution differs from transferrin receptor 1, increasing in differentiating hepatocytes and decreasing in differentiating erythroblasts. Expression of both receptors is cell cycle dependent. Mutations in the human transferrin receptor 2 gene cause iron overload disease, suggesting it has a role in iron homeostasis.     

Diabetogenic transferrin damages podocytes in early human diabetic nephropathy.

The exact mechanisms by which growth hormone (GH) damages the kidney inducing diabetic nephropathy has not yet been elucidated. Recently, it has been shown that transferrin has the same diabetogenic effects of GH, being its mediator. Transferrin was studied using immunohistochemistry and immunoelectron microscopy in cases of early diabetic nephropathy, and in controls. Transferrin was only found in diabetic cases in podocytes and Bowman's capsule cells, but also in the tubular cells of both diabetic and non-diabetic controls. Immuno-electron microscopy for the presence of transferrin showed positive signals in the cytoplasm of diabetic podocytes, but not in pedicels. This selective deposition was associated with signs of organelle and cytoskeleton damage. On the basis of previous evidence and present glomerular findings, these results suggest an indirect diabetogenic effect on the kidney by GH mediated through transferrin.     

Transferrin in fetal sheep cerebrospinal fluid and plasma during gestation

1. Transferrin concentrations in fetal sheep CSF and plasma have been estimated between 31 and 125 days gestation and in the adult, using a radial immunodiffusion assay. 2. The plasma concentration was lowest (183 +/- 35 mg/100 ml) in the earliest fetuses examined (31 days). It increased to over 350 mg/100 ml by 35 days; thereafter it was around the adult value (580 mg/100 ml). 3. In CSF the transferrin concentration increased from 43 +/- 10 mg/100 ml at 31 days to a maximum of 163 +/- 14 mg/100 ml at 40 days gestation after which it decreased considerably to 6.1 +/- 0.7 mg/100 ml at 125 days and was even lower in the adult (1.1 +/- 0.2 mg/100 ml). 4. CSF: plasma ratios for transferrin especially when compared with those of other plasma proteins, are not compatible with passive leakage of protein from blood to CSF in the developing brain. The results may be explained by specific transfer of proteins into CSF but synthesis by the choroid plexus or brain has not been excluded.     

Structure and expression of transferrin gene of channel catfish,Ictalurus punctatus

Transferrin is important in iron metabolism and has been reported to be involved in disease defence responses after bacterial infection. In this study, we identified, sequenced, and characterized the transferrin gene from channel catfish, Ictalurus punctatus. The catfish transferrin gene was similar to those of other vertebrate species with 17 exons and 16 introns. Sequence analysis indicated the presence of the two duplicated lobes, each containing two sub-domains separated by a cleft harboring the iron-binding site, suggesting their structural conservation. The channel catfish transferrin cDNA encodes 679 amino acids with 42–56% similarity to known transferrin genes from various species. Southern blot analysis suggested the presence of two copies of the transferrin gene in the catfish genome, perhaps arranged in a tandem fashion. The catfish transferrin gene was mapped to a catfish BAC-based physical map. The catfish transferrin gene was highly expressed in the liver, but expression was low in most other tested tissues. Transferrin expression was significantly up-regulated after infection with Edwardsiella ictaluri, the causative agent of enteric septicemia of catfish. Such induction was also found with co-injection of iron-dextran and E. ictaluri, while transferrin expression was not significantly induced with the injection of iron-dextran alone.     

Glycan uniformity within molecular variants of transferrin with distinct affinity for concanavalin A

Human serum Transferrin has been fractionated on concanavalin A-Sepharose column into three fractions: Con A-non reactive (5 %), Con A-weakly reactive (30 %) and Con A-reactive (65 %). Each Con A-affinity transferrin variant contains a pair of identical oligosaccharide units either tri-branched in the Con A-non reactive variant or two-branched in the Con A-weakly reactive and Con A-reactive transferrin. This is an additional support to our proposal that glycosylation occurs uniformly along each polypeptide chain yielding identical oligosaccharide units at each glycosylated site.     

Transferrin and ferritin endocytosis and recycling in guinea-pig reticulocytes

Transferrin and ferritin endocytosis and exocytosis by guinea-pig reticulocytes were studied using incubation with pronase at 4 degrees C to distinguish internalized and membrane-bound protein. Internalization of both transferrin and ferritin occurred in a time- and temperature-dependent fashion. Transferrin endocytosis was more rapid than that of ferritin. Transferrin binding to receptors was not altered, but transferrin endocytosis was decreased in the presence of ferritin. Iron accumulation from transferrin was inhibited by ferritin to a greater extent than could be accounted for by the decreased rate of endocytosis. In pulse-chase experiments, almost all of the transferrin was released intact from reticulocytes, but only about 50% of the total internalized ferritin was released, of which 85% was intact. The endocytosis of transferrin by rabbit reticulocytes was 2- to 2.5-times faster than guinea-pig reticulocytes. These data suggest that ferritin and transferrin are internalized by receptor-mediated endocytosis, possibly involving the same coated pits and vesicles, but that the proteins are recycled only partly in common.     

The role of the transferrin receptor in human B lymphocyte activation

Transferrin receptors are expressed on proliferating cells and are required for their growth. Transferrin receptors can be detected after, but not before, mitogenic stimulation of normal peripheral blood T and B cells. T cells demonstrate a functional requirement for transferrin receptors in the activation process. These receptors, in turn, are induced to appear by T cell growth factor (interleukin 2). In the experiments reported here, we examined the regulation of transferrin receptor expression on activated human B cells and whether these receptors are necessary for activation to occur. Activation was assessed by studying both proliferation and immunoglobulin secretion. We determined that transferrin receptor expression on B cells is regulated by a factor contained in supernatants of mitogen-stimulated T cells (probably B cell growth factor). This expression is required for proliferation to occur, because antibody to transferrin receptor (42/6) blocks B cell proliferation. Induction of immunoglobulin secretion, however, although dependent on phytohemagglutinin-treated T cell supernatant, is not dependent on transferrin receptor expression and can occur in mitogen-stimulated cells whose proliferation has been blocked by anti-transferrin receptor antibody. These findings support a model for B cell activation in which mitogen (or antigen) delivers two concurrent but distinct signals to B cells: one, dependent on B cell growth factor and transferrin receptor expression, for proliferation; and a second, dependent on T cell-derived factors and not requiring transferrin receptors, which leads to immunoglobulin secretion.     

Transferrin receptor induction is required for human B-lymphocyte activation but not for immunoglobulin secretion

Transferrin receptors are expressed on proliferating cells and are required for their growth. Transferrin receptors can be detected after, but not before, mitogenic stimulation of normal peripheral blood T and B cells. In the experiments reported here we have examined the regulation of transferrin receptor expression on activated human B cells and whether or not these receptors are necessary for activation to occur. Activation was assessed by studying both proliferation and immunoglobulin secretion. We have determined that transferrin receptor expression on B cells is regulated by a factor contained in supernatants of mitogen-stimulated T cells (probably B-cell growth factor). This expression is required for proliferation to occur, since antibody to transferrin receptor (42/6) blocks B-cell proliferation. Induction of immunoglobulin secretion, however, although dependent on PHA-treated T-cell supernatant, is not dependent on transferrin receptor expression and can occur in mitogen-stimulated cells whose proliferation has been blocked by antitransferrin receptor antibody. In addition, we have demonstrated that IgM messenger RNA induction following mitogen stimulation is unaffected by antitransferrin receptor antibody. These findings support a model for B-cell activation in which mitogen (or antigen) delivers two concurrent but distinct signals to B cells: one, dependent on B-cell growth factor and transferrin receptor expression, for proliferation, and a second, dependent on T cell-derived factors and not requiring transferrin receptors, which leads to immunoglobulin secretion.     

The mechanism of iron uptake by the rat placenta

The mechanism of iron uptake from transferrin by the rat placenta in culture has been studied. Transferrin endocytosis preceded iron accumulation by the cells. Both transferrin internalisation and iron uptake were inhibited by low temperature. Transferrin endocytosis was less susceptible to the effects of metabolic inhibitors such as sodium fluoroacetate, potassium cyanide, 2,4, dinitrophenol or carbonylcyanide M-chlorophenyl hydrazone (CCCP) than was iron uptake. Iron accumulation was decreased if the cells were incubated in the presence of weak bases such as chloroquine or ammonium chloride. These results suggest that, following internalisation, the vesicles containing the transferrin and iron became acidified, and that this acidification was a necessary prerequisite for the accumulation of iron by the cell. Further, the results indicate that the intravesicular pH was maintained at the expense of metabolic energy, suggesting that a pump may be involved. The importance of the permeability properties of the vesicle membrane in the iron uptake process was investigated by incubating the cells with labelled transferrin and iron in the presence of different cation and anion ionophores. Irrespective of the normal cation that the ionophores carried, all inhibited iron uptake without altering transferrin levels. In contrast, phloridzin, a Cl- transport inhibitor, did not affect either the levels of transferrin within the cells or the amount of iron accumulated.     

Transferrin and tooth morphogenesis: Retention of transferrin by mouse embryonic teeth in organ culture

Transferrin is the only serum protein that is required for the early morphogenesis of mouse embryonic teeth in organ culture. Transferrin is able to support tooth morphogenesis and dental cell differentiation by stimulating cell proliferation. Its role in this process is restricted exclusively to iron transport, which takes place by receptor-mediated endocytosis of iron-loaded transferrin. A lipophilic iron chelator, pyridoxal isonicotinoyl hydrazone (PIH), can replace transferrin and support tooth morphogenesis in organ culture. We studied the effects of these two iron transporters on cell proliferation in tooth germs during culture. We found that Fe-PIH and transferrin stimulate proliferation to a similar extent in early cap-stage teeth of 14-day mouse embryos, but have no effect on cell proliferation in bell-stage teeth of 16-day mouse embryos. Day-16 teeth undergo morphogenesis in unsupplemented chemically defined medium, whereas transferrin or Fe-PIH is needed for the morphogenesis of day-14 teeth. Although the need for exogenous iron-transport molecules is lost with advancing development, the level of mitotic activity is still fairly high in bell-stage teeth. The abundant binding of transferrin in areas of active cell proliferation in bell-stage teeth also suggests that transferrin is still needed and used for the transport of iron into proliferating cells. Transferrin is not degraded by the process of receptor-mediated endocytosis. After releasing iron into a cell, transferrin is returned to the extracellular space and is reused. We therefore studied whether the transferrin needed by bell-stage teeth could be adequately supplied by endogenous transferrin synthesized or stored in tissue explants.(ABSTRACT TRUNCATED AT 250 WORDS)     

Transferrin secretory pathways in rat parotid acinar cells

Transferrin is the major iron transporter in blood plasma, and is also found, at lower concentrations, in saliva. We studied the synthesis and secretion of transferrin in rat parotid acinar cells in order to elucidate its secretory pathways. Two sources were identified for transferrin in parotid acinar cells: synthesis by the cells (endogenous), and absorption from blood plasma (exogenous). Transferrin from both sources is secreted from the apical side of parotid acinar cells. Endogenous transferrin is transported to secretory granules. It is secreted from mature secretory granules upon stimulation with a β-adrenergic reagent and from smaller vesicles in the absence of stimulation. Exogenous transferrin is internalized from the basolateral side of parotid acinar cells, transported to the apical side by transcytosis, and secreted from the apical side. Secretory processes for exogenous transferrin include transport systems involving microfilaments and microtubules.     

Two new sheep transferrin variants and the effect of neuraminidase

Transferrin phenotypes were determined in six breeds of sheep by starch gel electrophoresis. Two new variants, Tf H_Czech and Tf K_Czech, were found and some evidence of their genetic control was obtained. Tf H_Czeeh was detected only in Sumava sheep; it has an intermediate mobility between Tf A and Tf B. Tf K_Czech was found only in Tsigais; it was localized between Tf B and Tf C. The frequencies of corresponding alleles were very low.
Individual transferrin variants (I, A, H_Czech, B, K_czech, C, D, E, and P) were treated with neuraminidase. Electrophoretic mobility of the strong band was decreased by two steps in each case. It suggests that in the strong Tf band two sialic acid residues are accessible to the enzyme.     

Inhibitory mechanism of lead on transferrin-bound iron uptake by rabbit reticulocytes: A fractal analysis

Experimental data of transferrin and transferrin-bound iron uptake byrabbit reticulocytes in the presence or absence of extracellular lead isanalyzed by means of a fractal model. A highly significant correlation offractal dimension (Df) of intracellular transferrin or transferrin-boundiron uptake with varying extracellular concentrations of lead (0 ~ 25umol/L) was observed (Transferrin: r = 0.897, p = 0.015; transferrin-boundiron: r = 0.947, p = 0.004). The Df of membrane-bound transferrin (r =-0.618, p = 0.191) or transferrin-bound iron (r = 0.144, p = 0.786) did notappear to be markedly altered by lead. Further analysis shows thatinhibitory degree of lead on intracellular iron uptake is higher than thaton intracellular transferrin uptake. These results suggest that theinhibitory effect of lead on the iron uptake may occur in intracellularprocess rather than in membrane binding step, probably inhibitingtranslocation of iron across the endosomal membrane.     

Constructing transferrin receptor targeted drug delivery system by using doxorubicin hydrochloride and vanadocene dichloride

Transferrin has shown potential in the delivery of anticancer drugs into primarily proliferating malignant cells that over-express transferrin receptors. Constructing transferrin receptor targeted drug delivery system has been widespread concerned. In this study, whether transferrin could transport noncovalent binding drugs into cancer cells has been investigated. Two representative compounds, doxorubicin hydrochloride (Dox) and vanadocene dichloride (Cp(2)VCl(2)), have been chosen to study the interactions with h-Tf and apo-Tf, and the influences in the presence of h-Tf and apo-Tf by using fluorescence spectroscopy, circular dichroism (CD) spectroscopy and MTT assay. The results have shown that both doxorubicin and Cp(2)VCl(2) could bind to h-Tf and apo-Tf but with different binding modes. The results of MTT assay demonstrate that the presence of both h-Tf and apo-Tf has enhanced the antiproliferative activity of Cp(2)VCl(2). However, the anticancer activity of the mixture of doxorubicin and h-Tf is basically the same as that of doxorubicin does. Our studies indicate that transferrin plays an important role in the transport and targeted delivery of Cp(2)VCl(2) into cancer cells.     

Natural selection promotes divergence of transferrin among salmonid species

Transferrin is an iron-binding protein that plays an important role in iron metabolism and resistance to bacterial infection in a variety of organisms. A comparison of transferrin coding sequences from four salmonid species shows that the rate of evolution at nonsynonymous sites is significantly higher than the rate at synonymous sites, suggesting that positive natural selection for new alleles has played an important role in the evolution of transferrin in some salmon species. We hypothesize that the selective agent driving rapid divergence is interactions between host transferrin and the iron-scavenging proteins of pathogenic bacteria.     

Transferrin and Transferrin Receptor Function in Brain Barrier Systems

1. Iron (Fe) is an essential component of virtually all types of cells and organisms. In plasma and interstitial fluids, Fe is carried by transferrin. Iron-containing transferrin has a high affinity for the transferrin receptor, which is present on all cells with a requirement for Fe. The degree of expression of transferrin receptors on most types of cells is determined by the level of Fe supply and their rate of proliferation.2. The brain, like other organs, requires Fe for metabolic processes and suffers from disturbed function when a Fe deficiency or excess occurs. Hence, the transport of Fe across brain barrier systems must be regulated. The interaction between transferrin and transferrin receptor appears to serve this function in the blood–brain, blood–CSF, and cellular–plasmalemma barriers. Transferrin is present in blood plasma and brain extracellular fluids, and the transferrin receptor is present on brain capillary endothelial cells, choroid plexus epithelial cells, neurons, and probably also glial cells.3. The rate of Fe transport from plasma to brain is developmentally regulated, peaking in the first few weeks of postnatal life in the rat, after which it decreases rapidly to low values. Two mechanisms for Fe transport across the blood–brain barrier have been proposed. One is that the Fe–transferrin complex is transported intact across the capillary wall by receptor-mediated transcytosis. In the second, Fe transport is the result of receptor-mediated endocytosis of Fe–transferrin by capillary endothelial cells, followed by release of Fe from transferrin within the cell, recycling of transferrin to the blood, and transport of Fe into the brain. Current evidence indicates that although some transcytosis of transferrin does occur, the amount is quantitatively insufficient to account for the rate of Fe transport, and the majority of Fe transport probably occurs by the second of the above mechanisms.4. An additional route of Fe and transferrin transport from the blood to the brain is via the blood–CSF barrier and from the CSF into the brain. Iron-containing transferrin is transported through the blood–CSF barrier by a mechanism that appears to be regulated by developmental stage and iron status. The transfer of transferrin from blood to CSF is higher than that of albumin, which may be due to the presence of transferrin receptors on choroid plexus epithelial cells so that transferrin can be transported across the cells by a receptor-mediated process as well as by nonselective mechanisms.5. Transferrin receptors have been detected in neurons in vivo and in cultured glial cells. Transferrin is present in the brain interstitial fluid, and it is generally assumed that Fe which transverses the blood–brain barrier is rapidly bound by brain transferrin and can then be taken up by receptor-mediated endocytosis in brain cells. The uptake of transferrin-bound Fe by neurons and glial cells is probably regulated by the number of transferrin receptors present on cells, which changes during development and in conditions with an altered iron status.6. This review focuses on the information available on the functions of transferrin and transferrin receptor with respect to Fe transport across the blood–brain and blood–CSF barriers and the cell membranes of neurons and glial cells.     

The human transferrin gene: 5' region contains conserved sequences which match the control elements regulated by heavy metals, glucocorticoids and acute phase reaction

Transferrin is a major plasma protein that transports iron to proliferating cells throughout the body. A clone containing the 5' region of the human transferrin gene has been isolated and characterized. A 14 kb EcoRI fragment was identified that contained the first 8 exons of the transferrin gene and 3.6 kb of its 5' flanking region. Conserved sequences identical or homologous to regulatory elements responding to heavy metals, glucocorticoid receptor and a putative acute phase reaction signal were identified in the 5'flanking region and intron 1. Also, the regulatory region of the transferrin gene contains a 14-bp sequence which closely matches sequences found in the interleukin-2 and gamma-interferon genes. All three genes are expressed by T lymphocytes before proliferation. A secondary loop structure similar to that proposed for the ovotransferrin gene can be formed by sequences in the 5' untranslated region of the transferrin mRNA.     

Une nouvelle fonction pour la transferrine exprimée par le testicule

In men, oligozoospermia corresponds with a low level of transferrin in semen. Transferrin appears to be a relevant indicator of gonadal function. Transferrin expression in normal testes is perfectly controlled. Transferrin contributes to iron transport. However, recent results show the existence of a dimeric form, which acts as a powerful regulator of phagocytosis of residual bodies by Sertoli cells. A disturbance of this new highlighted function may account for some forms of oligozoospermia.