Transferrin C subtypes and occupational photodermatosis of the face

In a factory in northern Sweden where 120 workers were uniformly exposed to photoactive substances 73 developed occupational facial eczema while 47 showed no reaction. The workers were examined with respect to 16 genetic marker systems: HLA, blood groups (ABO, Rh, MNSs, P, K, Le and Fy) and serum groups (Hp, Tf, Gc, Pi, Bf, C3, C4 and C6). Between reactors and nonreactors the following differences were found: (1) a significant decrease (p less than 0.05) of HLA A11 among the reactors; (2) a significant increase (p less than 0.05) of the C3 FS type among the reactors; (3) a highly significant increase (p less than 0.001) of the transferrin C2 gene and of the C2 variant among the reactors. The association with Tf C2 remained significant also after correction for number of significance tests. Since transferrin (iron) is known to catalyze the formation of hydroxyl radicals we hypothesize that the Tf C2 variant is more efficient in promoting radical formation and thereby cell damage. Other results supporting the notion that transferrin C2 may be associated with an increased susceptibility to toxic damage are discussed.     

Transferrin subtypes in Iran

The frequency of transferrin Tf C subtypes has been determined by double one-dimensional electrophoresis of plasma samples from Moslems (n = 91), Zoroastrians (n = 97), Jews (n = 88) and Armenians (n = 88) of Iran. The Zoroastrians show the lowest frequency of TfC1 (0.4999) and highest frequencies of TfC2 and TfC3 (.02215, and 0.2783, respectively). The Jews have the highest TfC1- and the lowest TfC2- and TfC3 frequencies (0.8011, 0.1478, and 0.0512, respectively). It could be shown that the differences between Zoroastrians and Jews are highly significant (p less than 0.001). Arbitrary subtyping of transferrin Tf B and TfD phenotypes could be done on samples from three regional groups of Iran: North: n = 282, Central: n = 548, and South: n = 587 into Tf B (Iran 1, 2, 3 and 4) and Tf D (Iran 1, 2 and 3) was performed according to mobilities relative to the transferrin C protein during polyacrylamide gel electrophoresis and by relative pI deviations from the Fe2-transferrin C1 protein after isoelectric focussing. The allele frequencies found in the total sample (n = 1417) are: TfB1 = 0.0003, TfB2 = 0.0010, TfB3 = 0.0042, TfB4 = 0.0007; TfD1 = 0.0017, TfD2 = 0.0014, and TfD3 = 0.0010.     

Transferrin subtypes and spontaneous abortion in a Chinese population

A series of Chinese newborns of consecutive normal vaginal deliveries were investigated for the distribution of serum transferrin subtypes by polyacrylamide gel iso-electric focusing at pH 3.5-9.5. Newborns whose mothers had a history of previous spontaneous abortion (n = 189) had a significantly higher frequency of the C2 variant and the C2 gene compared to those (n = 864) without a history of spontaneous abortion. There was no significant difference in the frequency of transferrin alleles between newborns with normal and low birth weight (n = 147).     

Transferrin subtypes in 11 south China minority populations.

Transferrin subtypes were determined by isoelectric focussing (IEF) in a total of 2,121 individuals from 11 South China minority populations. The C1, C2 and DCHI alleles were present in all the populations; B alleles were lacking, C4 was found in 3 populations and C3 in 6. C2 and C4 allele frequencies are notable in these minority groups. The frequency of the C2 allele was higher (0.25-0.38) than that of Han Chinese (0.18-0.25). In Bai the C2 frequency was as high as 0.38. The C4 allele was present at a low frequency (less than 0.01), which suggests that this allele probably existed in the ancestral Mongoloid population at a low frequency and increased in frequency in Amerindians due to genetic drift or other factors.     

Transferrin types in different ethnic groups of the USSR and Mongolia

Transferrin (TF) subtypes were studied in 7 different populations from the Soviet Union (Buryats, Russians, Koreans, Kirghizes and Pamirians) and in 3 different populations from Mongolia. The frequency of the C2 gene varied between 10.4% in Pamirians and 27.4% in Koreans and was generally higher in populations of Mongoloid origin. The frequency of the C3 gene was found to be very low (nonpolymorphic) in the Mongoloid groups, but it was also low (1.5%) in Russians. Rare B and D variants were found in 7 populations. The highest D frequencies were found in the Mongoloid populations.     

Glutamate-pyruvate transaminase subtypes in Singapore ethnic groups

Autopsy liver samples from 244 Chinese, 119 Malays and 136 Indians were screened for glutamate-pyruvate transaminase (GPT) subtypes by starch-gel electrophoresis and isoelectric focusing at pH 5-7. Altogether, ten phenotypes controlled by four alleles (GPT1, GPT2A, GPT2B and GPT3) were identified. There was no significant difference in the frequency of GPT alleles between the ethnic groups. The distribution of GPT types was in agreement with the Hardy-Weinberg equilibrium in all the ethnic groups.     

Transferrin in cultured human term cytotrophoblast cells: Synthesis and heterogeneity

Transferrin (Tf) mRNA was recently demonstrated in rat and mouseplacental tissue. Rat placental cells were shown to secrete transferrin. Thecell type with which Tf mRNA was associated was not investigated. Wetherefore studied the ability of immunopurified human term cytotrophoblastcells in culture to synthesize Tf, by means of pulse-label experiments with35S-methionine and report that these cells do synthesize Tf. Tf mRNA wasdemonstrated in the cell lysates by means of RT-PCR. Tf isolated fromcytotrophoblast and syncytiotrophoblast cells was shown to be different fromboth maternal and fetal serum Tf with respect to the distribution ofisoforms as demonstrated by means of iso-electric focusing. The iso-electricpoints were found at lower pH values (pH 5.0-5.4), compared to theiso-electric points of maternal and fetal serum Tf, suggesting a higherdegree of sialylation and glycan chain complexity.     

Transferrin subtypes in 51 Danish patients with hereditary haemochromatosis and in 847 normal subjects

Summary Transferrin (TF) subtypes were determined by isoelectric focusing in 51 unrelated Danish patients with hereditary haemochromatosis (HH) and in 847 normal subjects. The following TF phenotype frequencies were observed in HH patients and controls, respectively: TF*C1, 70.6% vs. 58.8%; TF*C2, 5.9% vs. 2.4%; TF* C3, 0% vs. 0.4%; TF*C1–2, 11.8% vs. 24.7%; TF*C1–3, 5.9% vs. 9.7%; TF*C2–3, 3.9% vs. 2.2%; TF*B–C1, 2.0% vs. 1.5%; TF*B–C2, 0% vs. 0.4%. None of these differences were statistically significant. There was no relationship between the TF subtypes and the clinical or paraclinical expression of disease in HH patients.     

Transferrin C2 and radiation-induced chromosomal damage

Radiation-induced chromosomal damage (after exposure to 1 Gy) in lymphocytes was studied in relation to transferrin C subtype (C1 vs. C2). In 72-hour lymphocyte cultures a significantly increased frequency of cells with radiation induced aberrations was observed in individuals with the transferrin type C2. Thus the results lend some support to the hypothesis that transferrin C2 may act as an enhancer of chromosomal damage.     

Transferrin subtypes and variants in Germany; Further evidence for a Tf null allele

Summary Isoelectric focusing (IEF) with carrier ampholytes was used for the determination of transferrin C subtypes and transferrin B and D variants in a sample of 1125 unrelated individuals from Southern Germany. The observed TfC allele frequencies were Tf*C1=0.7872, Tf*C2=0.1365, and Tf*C3=0.0675. The rare C subtype C6 was observed twice. A new C subtype, called C10, was observed and identified by IEF with immobilized pH gradients. The rare C subtypes C4 and C8 were also studied by this method. TfB and TfD variants were found with a heterozygous frequency of 1.53%. One new TfD was found which is located between D1 and D2 and therefore named D1-2. Evidence for a Tf null allele was obtained in a child and the putative father; they were considered to be heterozygous for an allele Tf0. The theoretical exclusion rate for paternity examinations was calculated for the Tf system and found to be 17.95%.     

Transferrin: Evidence for two common subtypes of the TfC allele

Summary Evidence is presented for an extended polymorphism of human transferrin (Tf). Three common phenotypes were observed among Tf^C individuals after isoelectric focusing of sera on polyacrylamide gels. They are explained in terms of two subtypes of the Tf^c allele, tentatively designated Tf^C1 and Tf^C2. The distribution of the phenotypes Tf C1, C2-1, and C2 provides a good fit to the Hardy-Weinberg equation. In our population sample (n=942) the following frequencies were calculated: Tf^C1=0.8195, Tf^C2=0.1720, Tf^B2=0.0064, Tf^B1–2=0.0016, and Tf^D1=0.0005. Family studies (n=112) indicate an autosomal codominant way of inheritance. The observed subheterogeneity is detectable in purified transferrin after isofocusing and subsequent immunofixation. The subtypes are still present after treatment of sera with neuraminidase.     

Transferrin C subtype frequencies in the Finnish population

Transferrin (Tf) C subtypes were determined in 419 unrelated adult Finns. The calculated gene frequencies were C1 = 0.738, C2 = 0.097 and C3 = 0.133. The Tf phenotypes in 150 mother-child pairs were in accordance with autosomal codominant inheritance. This material included a rare TfC allele product in three individuals, apparently the same in all cases.     

Transferrin C subtyping in Malaysians and in Indonesians from North Sumatra

Summary Malays, Chinese, and Indians from Peninsular Malaysia; Ibans and Bidayuh from Sarawak State; Kadazans from Sabah State, Northern Borneo; and Bataks, Minangkabau, and Javanese from North Sumatra, Indonesia, were subtyped for transferrin C by polyacrylamide gel isoelectric focusing. All nine populations studied are polymorphic for two alleles, Tf^C1 and Tf^C2. Tf^C3 was polymorphic in six populations and present as a rare variant in the other three. The frequency of Tf^C1 ranged from 0.855 in Bidayuh to 0.711 in Javanese, that of Tf^C2 from 0.231 in Indians to 0.113 in Bidayuh, and that of Tf^C3 from 0.030 in Javanese and Chinese to 0.008 in Bidayuh. Tf^Dchi is polymorphic in all the populations that we studied except in Minangkabau, in whom it is present as a rare variant, and in Indians, in whom it is absent.     

Analysis of heterogeneity in Fanconi's anemia patients of different ethnic origin

Summary Complementation studies based on mitomycin C sensitivity were performed on somatic cell hybrids between cells of a German patient with Fanconi's anemia and a Turkish, Arab, and Black African proband, respectively. Though the underlying genetic defects are expected to go back to different mutational events, the high rate of induced chromosomal aberrations in the hybrids clearly points to allelic mutations.     

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.     

Immunohistochemical Demonstration of Transferrin and Transferrin Receptor in Mammalian Integument

The present study demonstrates the distribution of transferrin and the transferrin receptor in the integument of eleven wild mammalian species using immunohistochemical methods. Both substances were regularly found in or near the peripheral cells of the sebaceous glands, especially of dense-haired animals. The transferrin receptor was also detectable in the epidermis, the secretory portion of tubular apocrine glands, and the outer epithelium of primary hair follicles. Transferrin as well as the transferrin receptor reacted strongly in macrophages of the papillary dermis only in the common seal. The results obtained are discussed with regard to possible biological functions in the skin of the substances demonstrated. Keywords: immunohistochemistry, integument, mammals, transferrin, transferrin receptor     

Protein kinase C subtypes in endothelial cells

Activation of protein kinase C (PKC) has been linked to the regulation of class II expression on endothelial cells by interferon-gamma (IFN-gamma). PKC subtypes in endothelial cells were analyzed using three different approaches, the immunoperoxidase staining of native and IFN-gamma stimulated cells cultured on chamber slides as well as immuno- and Northern blotting. All approaches revealed that of the conventional subtypes, alpha is the predominant form of PKC in endothelial cells. Even though IFN-gamma is able to induce PKC translocation to particulate fractions, no translocation was detected in histological stainings. Western blot studies as well as mRNA studies revealed that IFN-gamma is unable to increase the total amount of PKC in endothelial cells.