Targeted inhibition of transferrin-mediated iron uptake in Hep G2 hepatoma cells

We have used a model system consisting of two human hepatoma cell lines, Hep G2, representing well differentiated normal hepatocytes, and PLC/PRF/5, representing poorly differentiated malignant hepatocytes, to demonstrate that the differential presence of asialoglycoprotein receptor activity in these cell lines can be used to influence transferrin-mediated iron uptake. We based our experiments on the following facts: Hep G2 cells possess receptors that bind, internalize, and degrade galactose-terminal (asialo-)glycoproteins; PLC/PRF/5 cells have barely detectable asialoglycoprotein receptor activity; both cell lines possess active transferrin-mediated iron uptake; transferrin releases iron during acidification of intracellular vesicular compartments; primary amines, e.g. primaquine, inhibit acidification and iron release from transferrin. When added to culture medium, [55Fe]transferrin delivered 55Fe well to both cell lines. As expected, in the presence of [55Fe]transferrin, free primaquine caused a concentration-dependent decrease in 55Fe uptake in both cell lines. To create a targetable conjugate, primaquine was covalently coupled to asialofetuin to form asialofetuin-primaquine. When PLC/PRF/5 (asialoglycoprotein receptor (-)) cells were preincubated with this conjugate, transferrin-mediated 55Fe uptake was unaffected. However, transferrin-mediated 55Fe uptake by Hep G2 (asialoglycoprotein receptor (+)) cells under identical conditions was specifically decreased by 55% compared to control cells incubated without the conjugate.     

Factors influencing the uptake of iron and plutonium into cells

Uptake of 59Fe as well as 125I-labelled Fe-transferrin into HeLa cells points to the existence of a limited number of specific binding sites. This is in contrast to hepatocytes and hepatoma cells (Hep G2) where metal uptake from transferrin is very low, not saturable and cannot be prevented by an excess of the protein. Iron uptake into these cells is much higher from the citrate complex. The same is true for plutonium uptake into rat hepatocytes, while the uptake of this metal into Hep G2 cells is very small regardless of the ligand. In contrast to iron, plutonium presented as citrate is taken up into HeLa cells much better than plutonium presented as transferrin. The uptake of both metals from the citrate complex requires a high activation energy and can be prevented only by inhibition of oxidative phosphorylation. Other processes such as endocytosis, intactness of microtubuli, assembly of microfilaments or pH of the lysosomes do not seem to be of importance. Metal uptake from the citrate complex can be prevented only by the presence of other chelating agents and/or by transferrin. It can be assumed, therefore, that the metals react directly with constituents of the cell membrane, a process in which chelating agents can successfully compete if they form strong enough complexes with the metals.     

The hereditary hemochromatosis protein, HFE, specifically regulates transferrin-mediated iron uptake in HeLa cells

HFE is the protein product of the gene mutated in the autosomal recessive disease hereditary hemochromatosis (Feder, J. N., Gnirke, A., Thomas, W., Tsuchihashi, Z., Ruddy, D. A., Basava, A., Dormishian, F., Domingo, R. J., Ellis, M. C., Fullan, A., Hinton, L. M., Jones, N. L., Kimmel, B. E., Kronmal, G. S., Lauer, P., Lee, V. K., Loeb, D. B., Mapa, F. A., McClelland, E., Meyer, N. C., Mintier, G. A., Moeller, N., Moore, T., Morikang, E., Prasss, C. E., Quintana, L., Starnes, S. M., Schatzman, R. C., Brunke, K. J., Drayna, D. T., Risch, N. J., Bacon, B. R., and Wolff, R. R. (1996) Nat. Genet. 13, 399-408). At the cell surface, HFE complexes with transferrin receptor (TfR), increasing the dissociation constant of transferrin (Tf) for its receptor 10-fold (Gross, C. N., Irrinki, A., Feder, J. N., and Enns, C. A. (1998) J. Biol. Chem. 273, 22068-22074; Feder, J. N., Penny, D. M., Irrinki, A., Lee, V. K., Lebron, J. A., Watson, N. , Tsuchihashi, Z., Sigal, E., Bjorkman, P. J., and Schatzman, R. C. (1998) Proc. Natl. Acad. Sci. U S A 95, 1472-1477). HFE does not remain at the cell surface, but traffics with TfR to Tf-positive internal compartments (Gross et al., 1998). Using a HeLa cell line in which the expression of HFE is controlled by tetracycline, we show that the expression of HFE reduces 55Fe uptake from Tf by 33% but does not affect the endocytic or exocytic rates of TfR cycling. Therefore, HFE appears to reduce cellular acquisition of iron from Tf within endocytic compartments. HFE specifically reduces iron uptake from Tf, as non-Tf-mediated iron uptake from Fe-nitrilotriacetic acid is not altered. These results explain the decreased ferritin levels seen in our HeLa cell system and demonstrate the specific control of HFE over the Tf-mediated pathway of iron uptake. These results also have implications for the understanding of cellular iron homeostasis in organs such as the liver, pancreas, heart, and spleen that are iron loaded in hereditary hemochromatotic individuals lacking functional HFE.     

Effect of ATP depletion and temperature on the transferrin-mediated uptake and release of iron by BeWo choriocarcinoma cells.

We have recently described the transferrin-mediated uptake and release of iron by BeWo cells [van der Ende, du Maine, Simmons, Schwartz & Strous (1987) J. Biol. Chem. 262, 8910-8916]. We now extend our studies of the mechanisms responsible for uptake and release of iron by these cells. Following preloading, 59Fe release was maximal (about 12%) after about 4 h. Replacement of the extracellular medium with an equal volume of fresh medium either prior to or following the time at which equilibrium was reached further stimulated 59Fe release. Both the rate and maximum amount of iron release decreased if longer loading times were used. Preincubation of BeWo cells for 15 min with 10 mM-sodium cyanide and 50 mM-2-deoxyglucose prior to the determination of 59Fe release did not alter the amount released into medium (which did not contain a high-affinity iron chelator). However, under these conditions, the uptake of 59Fe was dramatically inhibited as a result of prolongation of the transferrin-transferrin-receptor complex recycling time. These results demonstrate that the release of iron from BeWo cells is independent of cellular ATP levels, whereas iron uptake is ATP-dependent. Rates of both 59Fe release and 59Fe uptake were temperature-dependent. Analysis of these data via an Arrhenius plot suggests a single rate-limiting step for the release and uptake processes between 0 and 37 degrees C. The apparent energies of activation of these processes are very similar (approx. 59.0 kJ/mol for iron release and 50.6 kJ/mol for iron uptake), which raises the possibility that the release and uptake of iron share a common thermodynamically rate-limiting step. Possible mechanisms involved in iron release out of the cell and out of the endosome are discussed.     

An iron-dependent mutant of Listeria monocytogenes of attenuated virulence

Abstract A bank of Tn 917 -insertional mutants from the facultative intracellular pathogen Listeria monocytogenes was screened by an original method based on bacterial growth on synthetic medium under iron-limiting conditions. One mutant, whose in vitro growth in synthetic medium was specifically dependent upon the availability of iron in its environment, was isolated and characterized. The insertional event occurred in a non-coding region, upstream of a rrn operon and located within a 1100-kb Not I fragment of the physical map, where the virulence genes already identified in L. monocytogenes were also present. Protein analysis by SDS-PAGE revealed a pleiotropic effect of the insertional event on cell-associated proteins, suggesting a polar effect of the transposon on adjacent unknown gene(s). The virulence in the mouse of this mutant was strongly impaired, although it was capable in vitro of growing intracellularly and of spreading from cell to cell, as shown by the production of lytic plaques on cell culture.     

An efficient biological pathway layout algorithm combining grid-layout and spring embedder for complicated cellular location information

Background  

Graph drawing is one of the important techniques for understanding biological regulations in a cell or among cells at the pathway level. Among many available layout algorithms, the spring embedder algorithm is widely used not only for pathway drawing but also for circuit placement and www visualization and so on because of the harmonized appearance of its results. For pathway drawing, location information is essential for its comprehension. However, complex shapes need to be taken into account when torus-shaped location information such as nuclear inner membrane, nuclear outer membrane, and plasma membrane is considered. Unfortunately, the spring embedder algorithm cannot easily handle such information. In addition, crossings between edges and nodes are usually not considered explicitly.     

An iron-dependent bacterial phospholipase D reminiscent of purple acid phosphatases

Recombinant phospholipase D (PLD) from Streptomyces chromofuscus (scPLD) has been characterized using colorimetric assays, spectroscopic investigations, and site-directed mutagenesis. scPLD, which shows phosphodiesterase activity toward a wide variety of phospholipids and phosphatase activity toward p-nitrophenyl phosphate, exhibits a visible absorption band with lambda(max) at 570 nm. Metal ion analysis performed by inductively coupled plasma mass spectroscopy shows the presence of approximately 1 equivalent of iron, 0.27 equivalent of manganese, and 0.1 equivalent of zinc per mole of protein as isolated. The metal ion content coupled with the visible absorption feature is compatible with the presence of Fe(3+)-tyrosinate coordination. When scPLD was dialyzed against solutions containing Mn(2+), Zn(2+) or EDTA, the Fe(3+) content was reduced to variable extents, and the residual specific activity correlated well with the residual iron content. Sequence homology with metal ion binding motifs in known alkaline phosphatases and purple acid phosphatase from red kidney bean shows that most of the residues involved in metal ion coordination are conserved among all the sequences considered. Mutation of some of these conserved residues (C123A, D151A, Y154F, and H391A) produced enzymes lacking iron with dramatically reduced PLD activity but little change in secondary structure or ability to bind to small unilamellar vesicles of phosphatidylcholine (with Ba(2+)) or phosphatidic acid. We suggest that scPLD is a member of a family of phosphodiesterase/phosphatases with structural and mechanistic similarity to iron-dependent purple acid phosphatases.     

Separate pathways for cellular uptake of ferric and ferrous iron

Separate pathways for transport of nontransferrin ferric and ferrous iron into tissue cultured cells were demonstrated. Neither the ferric nor ferrous pathway was shared with either zinc or copper. Manganese shared the ferrous pathway but had no effect on cellular uptake of ferric iron. We postulate that ferric iron was transported into cells via beta(3)-integrin and mobilferrin (IMP), whereas ferrous iron uptake was facilitated by divalent metal transporter-1 (DMT-1; Nramp-2). These conclusions were documented by competitive inhibition studies, utilization of a beta(3)-integrin antibody that blocked uptake of ferric but not ferrous iron, development of an anti-DMT-1 antibody that blocked ferrous iron and manganese uptake but not ferric iron, transfection of DMT-1 DNA into tissue culture cells that showed enhanced uptake of ferrous iron and manganese but neither ferric iron nor zinc, hepatic metal concentrations in mk mice showing decreased iron and manganese but not zinc or copper, and data showing that the addition of reducing agents to tissue culture media altered iron binding to proteins of the IMP and DMT-1 pathways. Although these experiments show ferric and ferrous iron can enter cells via different pathways, they do not indicate which pathway is dominant in humans.     

Paraquat and iron-dependent lipid peroxidation

The aim of this work was to study the effect of paraquat (P²⁺) on NADPH iron-dependent lipid peroxidation (basal peroxidation) either in the presence of NADPH or in the presence of NADPH-generating systems. When NADPH is present, P²⁺ potentiates NADPH iron-dependent lipid peroxidation, but use of NADPH-generating systems cancels this effect. This may be attributed to certain components in NADPH-generating systems such as glucose-6-phosphate and sodium isocitrate, which act as iron chelators. The binding of iron by these molecules facilitates its reduction and enhances its reactivity toward dioxygen molecules, leading to the formation of reactive species capable of initiating lipid peroxidation, such as Fe³⁺-O ₂ ⁻ . Under these conditions of rapid basal peroxidation, any additional reduction of iron(III) by a reduced form of P²⁺ (P^+.) has no apparent effect on the peroxidation itself, probably because the initial reaction between iron(II) and O₂ followed by initiation of the peroxidation are both rate-limiting steps in the process. Consequently, any alteration of the composition of the reacting mixture (e.g., buffers or the generating system) must be taken into consideration because the formation of new iron chelates can change the rate of basal peroxidation and will modify the effect of redoxcycling molecules.     

Transferrin-mediated gold nanoparticle cellular uptake

Targeted drug delivery is an important research area in specific therapy. Transferrin-conjugated nanoparticles are an attractive formulation as a vehicle for specific cellular uptake and targeted drug delivery. In this report, atomic force microscopy imaging was used to visualize the process of cellular uptake of transferrin-coupled gold nanoparticles on the surfaces of live cells for the first time. High-resolution images were captured, showing the endocytosis of transferrin-conjugated nanoparticles taking place during the process of internalization. This specific transferrin-mediated nanoparticle uptake was validated by confocal scanning imaging and transferrin competition experiments.     

Peptide-mediated cellular uptake of cryptophane

Cryptophane-A has generated considerable interest based on its high affinity for xenon and potential for creating biosensors for (129)Xe nuclear magnetic resonance (NMR) spectroscopy. Here, we report the cellular delivery of three peptide-functionalized cryptophane biosensors. Cryptophanes were delivered using two cationic cell penetrating peptides into several human cancer and normal cell lines. An RGD peptide targeting alpha(v)beta(3) integrin receptor was shown to increase specificity of cryptophane cell uptake. Labeling the peptides with Cy3 made it possible to monitor cellular delivery using confocal laser scanning microscopy. The peptido-cryptophanes were determined to be relatively nontoxic by MTT assay at the micromolar cryptophane concentrations that are required for (129)Xe NMR biosensing experiments.     

A structural basis for cellular uptake of GST-fold proteins

It has recently emerged that glutathione transferase enzymes (GSTs) and other structurally related molecules can be translocated from the external medium into many different cell types. In this study we aim to explore in detail, the structural features that govern cell translocation and by dissecting the human GST enzyme GSTM2-2 we quantatively demonstrate that the α-helical C-terminal domain (GST-C) is responsible for this property. Attempts to further examine the constituent helices within GST-C resulted in a reduction in cell translocation efficiency, indicating that the intrinsic GST-C domain structure is necessary for maximal cell translocation capacity. In particular, it was noted that the α-6 helix of GST-C plays a stabilising role in the fold of this domain. By destabilising the conformation of GST-C, an increase in cell translocation efficiency of up to ～2-fold was observed. The structural stability profiles of these protein constructs have been investigated by circular dichroism and differential scanning fluorimetry measurements and found to impact upon their cell translocation efficiency. These experiments suggest that the globular, helical domain in the 'GST-fold' structural motif plays a role in influencing cellular uptake, and that changes that affect the conformational stability of GST-C can significantly influence cell translocation efficiency.     

Oleic acid uptake and binding by rat adipocytes define dual pathways for cellular fatty acid uptake

Oleic acid (OA) uptake by rat adipocytes and the proportions of intracellular unesterified [3H]OA and its 3H-labeled esters were determined over 300 s. Uptake was linear for 20;-30 s, with rapid esterification indicating entry into normal metabolic pathways. Initial rates of OA uptake and its binding to plasma membranes were studied over a spectrum of oleic acid:bovine serum albumin (BSA) ratios, and expressed as functions of unbound OA concentrations calculated with both the 1971 OA:BSA association constants of Spector, Fletcher, and Ashbrook and more recent constants (e.g., the 1993 constants of Richieri, Anel, and Kleinfeld), which generate concentrations 10- to 100-fold lower. In either case, uptake was the sum of saturable and linear processes, with > or =90% occurring via the saturable pathway when the OA:BSA molar ratio was within the physiologic range (0.5;-3.0). Within this range, rate constants for saturable transmembrane influx (k(s)), calculated from both sets of constants, were similar (2.9 s(-1)) and were 10- to 30-fold faster than those for nonsaturable uptake (k(ns) = 0.26;-0.10 s(-1), t1/2 = 2.7;-6.6 s, based on the constants of Spector et al. and Richieri et al., respectively). The rate of oleic acid flip-flop into rat adipocytes (k(ff) = 0.16 +/- 0.02 s(-1), t1/2 = 4.3 +/- 0.5 s), computed from published data, was similar to k(ns). Thus, OA uptake occurs by both a saturable mechanism and passive flip-flop. This conclusion is independent of the OA:BSA association constants used to analyze the experimental measurements.     

Reducible siRNA dimeric conjugates for efficient cellular uptake and gene silencing

In this study, dimerized siRNAs linked by a cleavable disulfide bond were synthesized for efficient intracellular delivery and gene silencing. The reducible dimerized siRNAs showed far enhanced complexation behaviors with cationic polymers as compared to monomeric siRNA at the same N/P ratio, as demonstrated by microscopic techniques and gel characterization. Dimerized siRNAs targeting green fluorescent protein (GFP) or vascular endothelial growth factor (VEGF) were complexed with linear polyethylenimine (LPEI), and treated to various cell lines to examine gene transfection efficiencies. In comparison to monomer siRNA/LPEI complexes, dimeric siRNA/LPEI complexes showed greatly enhanced cellular uptake and gene silencing effects in vitro. These results were mainly due to the higher charge density and promoted chain flexibility of the dimerized siRNAs, providing more compact and stable siRNA complexes. In addition, the conjugation strategy of reducible siRNA dimers was further extended: poly(ethylene glycol) (PEG)-modified dimerized siRNAs and heterodimers of siRNAs targeting two different genes (e.g., GFP and VEGF) were synthesized, and their gene silencing efficiencies were characterized. The dimerized siRNA complex system holds great potential for in vivo systemic gene therapy.     

Synthesis and characterization of a novel arginine-grafted dendritic block copolymer for gene delivery and study of its cellular uptake pathway leading to transfection

We synthesized a novel arginine-grafted dendritic block copolymer, R-PAMAM-PEG-PAMAM-R G5 (PPP5-R) for gene delivery systems. Its Mw was measured as 2.74 x 104 Da by MALDI-TOF, and approximately 36 arginine residues are found to be grafted to the polymer by 1H NMR. PPP5-R was able to form polyplexes with plasmid DNA, the average size of which was about 200 nm. Positive zeta-potential values (+22 to +28 mV) of PPP5-R polyplex indicate the formation of positively charged stable polyplex particles and suggest that large dendritic blocks with high positive charge may not be fully shielded by PEG chains even after PEG-coated complex formation. PPP5-R polyplex shows enhanced water solubility due to the polymer's PEG core and also shows low cytotoxicity, representing the potential for in vivo application. We identified the greatly enhanced transfection efficiency of PPP5-R in comparison with that of native PPP5 on various cell lines. Moreover, in view of the result of various cellular uptake inhibitor treatments during a transfection step, the cellular uptake of PPP5-R polyplex leading to effective transfection is thought to be not dependent on one exclusive pathway and to have the possibility of multiple pathways (caveolae-, clathrin-, and macropinocytosis-mediated pathways), contrary to the caveolae-dependent uptake of the PPP5 polyplex lacking arginine residues.     

Synthesizing and staining manganese oxide nanoparticles for cytotoxicity and cellular uptake investigation

Background

For decades, contrast agents have been used to reduce longitudinal (T₁) or transverse (T₂) relaxation times. High toxicity of gadolinium-based contrast agents leads researchers to new T₁ contrast agents. Manganese oxide (MnO) nanoparticle (NP) with the lower peril and good enough signal change ability has been offered as a new possibility for magnetic resonance imaging (MRI).

Methods

The synthesized NPs were investigated for physicochemical and biological properties by X-ray diffraction, Fourier transform infrared spectroscopy, transmission electron microscope, dynamic light scattering (DLS), inductively coupled plasma, enzyme-linked immunosorbent assay, and 3 T magnetic resonance imaging.

Results

Due to physical contact importance of T₁ contrast agents with tissues' protons, extremely thin layer of the surfactant, less than 2 nm, was coated on NPs for aqueous stabilizing. The hydrophilic gentisic acid with low Dalton, around 154, did that role truly. Moreover, decreasing NP size to 5 nm which increases available surface for the proton relaxation is another important parameter to reach an appropriate longitudinal relaxation rate. The NPs didn't reveal any side effects on the cells, and cellular uptake was considerable.

Conclusions

The synthesized NPs represented a promising result in comparison to clinical gadolinium chelates, due to higher r₁ relaxivity and lower toxicity.

General significance

In addition to considerable signal change and cellular uptake, Prussian blue was tried on MnO NPs for the initial time, which can be observed within cells by pale blue color.     

Understanding the cellular uptake of phosphopeptides

Phosphopeptide-cellular uptake has been studied with a unique combination of tools designed to quantitate this phenomena and to understand properties that contribute to transmembrane penetration. High-affinity src-homology domain (SH2) hexapeptides for the phosphatidyl inositol 3-kinase system were used to judge cell penetration using red blood cells—a model system for the study of transmembrane cellular uptake. Hexapeptides without phosphate groups and devoid of charged residues poorly entered cells. N-terminal modification with bulky hydrophobic groups enhanced partitioning into octanol, an index of hydrophobicity, and allowed certain non-phosphorylated peptides to pass into red cells. However, tyrosine phosphorylation of hexapeptides markedly decreased octanol-water partitioning and completely eliminated cellular uptake. Inclusion of ion-pairing agents that masked the phosphate hydrophilic character enabled partitioning of phosphopeptides into octanol and achieved cellular uptake. This effect was demonstrated using fluorescent derivatives of phosphopeptides and CV1 cells in culture. The results validate the concept of facilitating cell entry by charge masking and open the way to future refinements of this principle. Various penetration techniques are compared and discussed in the context of maximizing cellular viability.     

Sodium concentrations affect metabolite uptake and cellular metabolism

Rates of uptake of glucose (measured with 3H-2-deoxy-d-glucose), galactose, and leucine after exposure of chick embryo cells to increasing concentrations of Na+ over the range 100 to 200 mM. Uptake of nucleosides was unaffected by [Na+] over this range. Prior exposure of cells was required for the [Na+] effect on uptake. Changes were measureable within two hours after changing [Na+], and although the capacity for deoxyglucose uptake remained constant thereafter, the capacity for leucine uptake continued to change during the next few hours. Inhibition of protein synthesis by cycloheximide, or of RNA synthesis by Actinomycin D, failed to prevent these uptake changes. Analysis of the kinetics of uptake showed that only the Km for uptake of deoxyglucose or leucine was affected by [Na+]; the maximum V for each compound remained the same. Effects of [Na+]; could be distinguished from the increased capacity for glucose uptake induced by glucose starvation. Incorporation of both radioactive uridine into RNA, and radioactive thymidine into DNA, were affected by [Na+[, but the differences were not correlated with uptake of other metoblites. No differences in countable mitoses were apparent, although the growth of chick embryo cells in increased slightly with increasing [Na+]. Changes in uptake due to differing [Na+] also were observed in mammalian (rat NRK) cells. However, no effects of [Na+] on rates of cell growth or saturation density were observed with these cells.