Ferric cacodylate efficiently stimulates growth of rat renal glomerular epithelial cells in vitro

Rat renal glomerular epithelial cells (SGE1 cell line) can be maintained and grown continuously in serum-free medium supplemented with insulin, iron-saturated transferrin (Tr), selenium, bovine serum albumin (BSA), linoleic acid, and epidermal growth factor (EGF). Of the growth supplements used, Tr is essential for proliferation of the cells. In the present study, we describe the use of a unique iron-chelate complex, ferric cacodylate (Fe-Cac), positively charged molecules in neutral buffer, that could almost replace Tr in serum-free culture. It even stimulated the growth of SGE1 cells more efficiently than ferric chloride (FeCl₃) and other iron-chelate complexes, such as ferric nitrilotriacetate (Fe-NTA) and ferric citrate (Fe-Cit). The growth-stimulatory activity of Fe-Cac was exerted at iron concentrations of more than 0.01 g/ml, whereas a 10-fold excess of iron concentration was required with FeCl₃, Fe-NTA and Fe-Cit. We observed that SGE1 cells grew until confluent, then formed hemicysts (domes) in serum-free medium containing Fe-Cac, suggesting that Fe-Cac did not merely permit cell growth but also supported polarization and organization of the cells into a functional epithelial architecture. Moreover, since the stimulatory activity of Fe-Cac was completely abolished by desferrioxamine, a strong iron chelator, it is suggested that iron is crucial for growth of SGE1 cells. When the cells were treated with suramin, an inhibitor of cellular pinocytosis and endocytosis of a large spectrum of ligands including receptor-bound growth factors, growth-stimulatory activity of Tr was inhibited, whereas the activity of Fe-Cac was not affected. These results, taken together, strongly suggest that the growth-stimulatory activity of Fe-Cac is associated with iron delivery into the cells through the cell membrane by diffusion, which is different from Tr receptor-mediated endocytosis. The use of Fe-Cac for investigating iron-regulated cell proliferation is suggested.     

Subdivision of equine Tf into H1 and H2

Subdivision of equine TfH into two variants, designated H1 (faster) and H2 (slower), has been accomplished by high voltage, thin layer polyacrylamide gel electrophoresis at pH 7.9. Transferrin H1 and H2 have been shown to be controlled by codominant alleles and gene frequencies of the Tf alleles have been determined in the Australian Thoroughbred, Standardbred. Quarter Horse and Arabian Horse breeds.     

Inhibition of endocytosis from coated pits by acidification of the cytosol

Binding and endocytosis of the ligands transferrin, epidermal growth factor (EGF), and ricin were measured in a number of different cell lines after treatment of cells with compounds that react with SH-groups and under conditions where the cytosolic pH was lowered. N-ethylmalemide and diamide irreversibly inhibited endocytosis of all ligands tested, whereas low pH in the cytosol strongly inhibited endocytosis of transferrin and EGF. Data obtained by electron microscopy indicated that the formation of coated vesicles from coated pits is inhibited in acidified cells. Entry of ricin was much less affected, and ricin endocytosed under these conditions was able to intoxicate the cells. At low pH in the cytosol there was a calcium-dependent increase in the number of transferrin receptors at the cell surface. The increase was even larger in the presence of the calcium ionophore A23187, whereas it was completely blocked by the calmodulin antagonists trifluoperazine and W7. The results show that endocytosis from coated pits can be inhibited in a reversible way by acidification of the cytosol and they suggest that a second pathway of endocytosis exists, possibly involving formation of vesicles from uncoated areas of the membrane.     

Effect of transferrin on amphibian limb regeneration: a blastema cell culture study

Summary In order to study mitogenic control during axolotl limb regeneration, we have developed a primary blastema cell culture as a very sensitive bioassay for blastema mitogens. Transferrin, an iron-binding glycoprotein which has been shown to be the neurotrophic factor for muscle cells, is the mitogen which has been analysed in the present report. Addition of approximately 2 g human transferrin/ ml of serum-free culture medium enhances blastema cell proliferation 11-fold over control levels and 2-fold over that produced by the addition of nerve extracts or purified growth factors extracted from nerve tissues (basic and acidic fetal growth factor, FGF). At a higher concentration (20 g/ml), transferrin alone has no mitogenic effect unless the medium is also supplemented with FeCl₃ (100 M). The results are discussed with regard to the sensitivity of the blastema cell culture bioassay and in the context of the neurotrophic theory of urodele limb regeneration.     

转铁蛋白结构与功能的研究——骆驼血清转铁蛋自的分离纯化及其含单一铁结合部位的结构域的制备和鉴定

分离纯化获得的骆驼血清转铁蛋白由分子量为73,000和63,000两个组分组成。两者至少N-端五肽顺序相同(Met-Pro-Asp-Lys-Thr)。骆驼血清转铁蛋白在生理pH下不能与人胎盘转铁蛋白受体结合。用胰蛋白酶酶解骆驼转铁蛋白可以同时得到两个合单一铁结合部位的结构域,分别来自转铁蛋白分子的N-端称N-端结构域(分子量34,700和40,700)和C-端称C-端结构域(分子量35,100)。在上述结果的基础上指出并讨论了反刍动物转铁蛋白在结构和功能上存在更多的共同性,而与其它哺乳动物的转铁蛋白有着明显的区别。     

Species specificity of iron delivery in hybridomas

Summary Studies with Human x Human (HxH), Human x Mouse (HxM), and Mouse x Mouse (MxM) hybridomas have enabled us to define specific factors that affect hybridoma growth in a species-specific manner. Three transferrins and three lipophilic iron chelates have been tested for their ability to support hybridoma proliferation and antibody production. The results of these studies demonstrate that HxH hybridomas do not respond to bovine transferrin a⁺ concentrations up to 100 μg/ml and are approximately 100-fold less responsive to mouse transferrin than to human transferrin. HxM and MxM hybridomas respond equally to human or mouse transferrin but are 100-fold less sensitive to bovine transferrin. An antibody to the human transferrin receptor inhibited the growth-promoting activity of human or mouse transferrin on HxH hybridomas but was ineffective on HxM hybridomas. This semonstrated the functionality of the human transferrin receptor in HxH hybridomas and that human, mouse, and bovine transferrin were interacting through the mouse transferrin receptor in HxM hybridomas. HxH and HxM hybridomas respond similarly to three different iron chelates exhibiting 80 to 110% of the growth response to human transferrin. MxM hybridomas fail to respond to the iron chelates at similar concentrations, suggesting that the human genome present in the other hybridoma species confers a unique ability for utilizing iron when delivered in this form.     

Growth of H-35 rat hepatoma cells in unsupplemented serum-free media: Effect of transferrin,insulin and cell density

Summary Serum-free tissue culture medium consisting of a 1∶1 mixture of Dulbecco's modified Eagle's medium (DMEM) and Ham's F12 medium is herein shown to support growth of Reuber H-35 cells over several days in culture. Cells were initially plated in serum containing DMEM medium for 3 h. After cell attachment, serum is removed and replaced with a serum-free 1∶1 mixture of these two commercially available tissue culture media. The doubling time of cell growth in this unsupplemented serum-free medium was 46 h in lightly plated cultures over the first 5 d. The presence of transferrin (5 μg/ml) and insulin (3.3 nM) results in a cell doubling time of 17 h, which equaled the growth rate in medium containing 10% fetal bovine serum. In the absence of transferrin, growth rates in serum-free medium were correlated with the cell density of cultures. Conditioned medium from dense, serum-free cultures has growth-stimulating activity in recipient lightly plated cultures. This simple, serum-free culture medium will facilitate studies on the growth regulation of H-35 rat hepatoma cells. This work was funded by a feasibility grant from the American Diabetes Association, as well as by the National Institutes of Health grants CA 24604-09 and CA 16463-14.     

Transferrin and iron requirements of embryonic mesoderm cells cultured in hydrated collagen matrices

Summary Very early embryonic mesoderm cells were taken from the primitive streak-stage chick embryo and cultured in a matrix of type I collagen in the presence of serum. Previous work has shown that under these conditions cells do not leave the explant and move in the collagen in the absence of supplemented avian transferrin. Cells explanted onto tissue culture plastic in the presence of serum do not require this transferrin supplement. These observations were investigated further by culturing cells in collagen in the presence of the lipophilic iron chelator, ferric pyridoxal isonicotinoyl hydrazone (FePIH), which can replace transferrin as an iron-delivery agent. Under conditions in which FePIH could effectively stimulate chick embryo myoblast growth, no such long-term stimulation was obtained with the early mesoderm cells in collagen. This suggested that for mesoderm cells, FePIH could not replace transferrin. Antibody to the transferrin receptor and to transferrin itself inhibited growth of myoblasts in collagen and on plastic, and of mesoderm cells in collagen. Mesoderm cells on plastic, however, were refractory to the presence of the antibody directed to the receptor and seemed to show a low dependency on transferrin-delivered iron under these conditions, inasmuch as antiserum to transferrin itself only caused a partial inhibition of outgrowth. The results suggest that mesoderm cells in collagen require transferrin for both iron uptake and for another unspecified function. It is consistent with the results to propose that transferrin binding might modulate the cells' attachment to collagen, thus influencing outgrowth. The distribution of the actin cytoskeleton in mesoderm cells actively migrating in collagen, such as in the presence of transferrin, suggests a stronger attachment to the collagen than nonmigrating cells. This work was supported by an operating grant from the Medical Research Council of Canada.     

Immunohistochemical localization of the transferrin receptor in the seminiferous epithelium of the rat

The transferrin receptor has been immunohistochemically localized in the seminiferous epithelium of the rat with a monoclonal antibody, MRC OX26, which recognizes the transferrin receptor glycoprotein. The receptor was detectable on mitotically and meiotically dividing germ cells and, less abundantly, on round spermatids. It was lost from germ cells during spermatid elongation and was undetectable on immature spermatozoa. The transferrin receptor was also present on Sertoli cells in the testes of immature animals and on Sertoli cells in the testes of aspermatogenic animals that had been irradiated in utero. It was not detectable on Sertoli cells in the testes of cryptorchid animals. These studies demonstrate that the transferrin receptor is abundant on dividing germ cells as well as dividing somatic cells.