Regulation of K562 cell transferrin receptors by exogenous iron

Single-cell analysis of K562 human erythroleukemia cells by flow cytometry was used to demonstrate the specific role of iron in regulating transferrin receptors (TfRs) and to establish that TfR expression does not necessarily correlate with growth rate. Exogenous iron concentration in culture was manipulated by supplementing the medium with sera having different iron concentrations over the range 0.6 to 5.4 micrograms/ml, by the addition of iron in the form of FeCl3, iron-saturated serum, or diferric transferrin, and by the addition of the iron chelator Desferal (desferrioxamine). TfR expression was negatively correlated with exogenous iron content: any treatment that reduced exogenous iron supply by at least 15% resulted in as much as a 1.8-fold increase in external receptors, detected as binding by both transferrin and monoclonal anti-TfR antibodies, and a 1.5-fold increase in the pool of internal receptors, as detected by anti-TfR antibody binding. None of these treatments altered growth rate, total cellular protein content, protein synthetic rate, cell cycle distribution or cell size. The rapid (12 hr) and reversible induction of internal and external receptors by Desferal was inhibited by cycloheximide and therefore may have resulted from de novo synthesis and not just mobilization of internal receptor pool to the cell surface. The correlation between growth rate and TfR expression previously observed in these and other cells must be secondary to cellular mechanisms that maintain intracellular iron pools by regulating synthesis, recycling, and cell surface expression of TfRs.     

Internalization efficiency of the transferrin receptor.

Quantitative ultrastructural and biochemical methods have allowed us to obtain a coherent set of data on the internalization efficiency of the transferrin receptor (TfR). In confluent cell cultures we find that (1) the initial internalization rate of transferrin is approximately 10% per minute, and (2) around 10% of cell-surface TfRs are present in coated pits. From these data a lifetime of coated pits of ca. 1 min is derived. Furthermore, we show that coated pits constitute 1.1-1.4% of the plasma membrane area in confluent cell cultures. Thus, the TfR is concentrated six- to ninefold in coated pits compared to resident plasma membrane proteins. Moreover, we show that the concentration of TfRs in coated pits is cell density dependent, since only around 5% of the receptors are present in coated pits in low-density cultures. Correspondingly, the internalization of TfRs in high-density cell cultures is roughly twice as efficient as that in low-density cell cultures. The reduced TfR internalization efficiency at low cell density is accounted for by a concomitant decrease to 0.55% in the relative surface area occupied by coated pits.     

Expression of membrane activation antigens on murine B lymphocytes stimulated with lipopolysaccharide

The expression of two membrane glycoproteins, RL388 antigen and transferrin receptor (TfR), was examined on murine B cells stimulated with lipopolysaccharide (LPS) in vitro. Immunofluorescent staining with monoclonal antibodies and flow cytofluorometric analysis were used to monitor the expression of these markers as a function of the time in culture, the state of membrane Ia antigen expression, the position in cell cycle, and the degree of B-cell differentiation. Freshly explanted splenic B cells expressed low levels of RL388 antigen and TfR. Following LPS stimulation, increased expression of RL388 antigen was detectable by 8 to 12 hr of culture, a time span characterized by increased Ia antigen expression, blast transformation, and G0 to G1 phase transition. The increased expression of TfR was apparent later and correlated with entry into late G1 phase and the onset of S phase. LPS-stimulated cell cultures treated with actinomycin D (G0/G1 block) exhibited increased expression of Ia antigen, but neither RL388 antigen nor TfR, whereas hydroxyurea treatment (G1/S block) allowed expression of all three markers. These results indicate that hyperexpression of RL388 antigen and TfR occurs during G1 phase and that these events are subsequent to Ia antigen hyperexpression. Finally, B cells in late G1 through M phase of the cell cycle simultaneously express high levels of RL388 antigen and TfR. These findings suggest that the expression patterns of RL388 antigen and TfR might be useful parameters for defining compartments of the murine B-cell cycle.     

Parvovirus infection of cells by using variants of the feline transferrin receptor altering clathrin-mediated endocytosis, membrane domain localization, and capsid-binding domains

The feline and canine transferrin receptors (TfRs) bind canine parvovirus to host cells and mediate rapid capsid uptake and infection. The TfR and its ligand transferrin have well-described pathways of endocytosis and recycling. Here we tested several receptor-dependent steps in infection for their role in virus infection of cells. Deletions of cytoplasmic sequences or mutations of the Tyr-Thr-Arg-Phe internalization motif reduced the rate of receptor uptake from the cell surface, while polar residues introduced into the transmembrane sequence resulted in increased degradation of transferrin. However, the mutant receptors still mediated efficient virus infection. In contrast, replacing the cytoplasmic and transmembrane sequences of the feline TfR with those of the influenza virus neuraminidase (NA) resulted in a receptor that bound and endocytosed the capsid but did not mediate viral infection. This chimeric receptor became localized to detergent-insoluble membrane domains. To test the effect of structural virus receptor interaction on infection, two chimeric receptors were prepared which contained antibody-variable domains that bound the capsid in place of the TfR ectodomain. These chimeric receptors bound CPV capsids and mediated uptake but did not result in cell infection. Adding soluble feline TfR ectodomain to the virus during that uptake did not allow infection.     

Residues in the apical domain of the feline and canine transferrin receptors control host-specific binding and cell infection of canine and feline parvoviruses

Canine parvovirus (CPV) and feline panleukopenia virus (FPV) capsids bind to the transferrin receptors (TfRs) of their hosts and use these receptors to infect cells. The binding is partially host specific, as FPV binds only to the feline TfR, while CPV binds to both the canine and feline TfRs. The host-specific binding is controlled by a combination of residues within a raised region of the capsid. To define the TfR structures that interact with the virus, we altered the apical domain of the feline or canine TfR or prepared chimeras of these receptors and tested the altered receptors for binding to FPV or CPV capsids. Most changes in the apical domain of the feline TfR did not affect binding, but replacing Leu221 with Ser or Asp prevented receptor binding to either FPV or CPV capsids, while replacing Leu221 with Lys resulted in a receptor that bound only to CPV but not to FPV. Analysis of recombinants of the feline and canine TfRs showed that sequences controlling CPV-specific binding were within the apical domain and that more than one difference between these receptors determined the CPV-specific binding of the canine TfR. Single changes within the canine TfR which removed a single amino acid insertion or which eliminated a glycosylation site gave that receptor the expanded ability to bind to FPV and CPV. In some cases, binding of capsids to mutant receptors did not result in infection, suggesting a structural role for the receptor in cell infection by the viruses.     

Recycling kinetics and transcytosis of transferrin in primary cultures of bovine brain microvessel endothelial cells

Primary cultures of bovine brain microvessel endothelial cells (BMECs) were used to examine the cycling kinetics of ferrotransferrin (Tf) and to provide evidence for a transcytotic pathway in vitro. Binding of 125I-Tf to BMECs grown on matrix-coated plastic was measured in the presence of saponin to calculate the total number of transferrin receptors (TfRs). Nonlinear regression analysis of the binding isotherm showed that there were 100,000 high-affinity receptors per cell and that expression was maximum at cell confluence. Binding of Tf at 4 degrees C indicated that there was a large intracellular receptor pool comprising 85-90% of the total cellular receptors. Accumulation of Tf at 37 degrees C, inhibited at low temperature and in the presence of metabolic poisons, occurred with an initial rate coefficient of 0.030 min-1 and this decreased by 83% after 60 min. Concomitant accumulation of 59Fe from Tf-59Fe was linear. In the absence of externally added ligand, 80% of the accumulated 125I-Tf was released into the medium with a rate coefficient of 0.017 min-1 and this was inhibited at low temperature. In the presence of the weak base primaquine, the accumulation of Tf and 59Fe and the efflux of Tf were decreased. Moreover, phorbol myristate acetate (PMA) caused a 30% increase in surface TfRs and an 82% increase in Tf accumulation, although the size of the recycling pool remained unchanged. Despite the low numbers of TfR expressed by post-confluent cells, filter-grown BMEC monolayers were used to measure transcytosis of Tf. A small portion of the Tf that was accumulated from the apical side entered a transcytotic pathway. Most of the Tf and all of an accumulated fluid-phase tracer were recycled towards the apical side. These results showed that cultured BMECs cycle Tf-TfR complexes slowly and vectorially and suggested that the large intracellular receptor pool may facilitate steady state accumulation and regulate transcellular transport of iron.     

Transferrin receptor 2-alpha supports cell growth both in iron-chelated cultured cells and in vivo

In most cells, transferrin receptor (TfR1)-mediated endocytosis is a major pathway for cellular iron uptake. We recently cloned the human transferrin receptor 2 (TfR2) gene, which encodes a second receptor for transferrin (Kawabata, H., Yang, R., Hirama, T., Vuong, P. T., Kawano, S., Gombart, A. F., and Koeffler, H. P. (1999) J. Biol. Chem. 274, 20826-20832). In the present study, the regulation of TfR2 expression and function was investigated. A select Chinese hamster ovary (CHO)-TRVb cell line that does not express either TfR1 or TfR2 was stably transfected with either TfR1 or TfR2-alpha cDNA. TfR2-alpha-expressing cells had considerably lower affinity for holotransferrin when compared with TfR1-expressing CHO cells. Interestingly, in contrast to TfR1, expression of TfR2 mRNA in K562 cells was not up-regulated by desferrioxamine (DFO), a cell membrane-permeable iron chelator. In MG63 cells, expression of TfR2 mRNA was regulated in the cell cycle with the highest expression in late G(1) phase and no expression in G(0)/G(1). DFO reduced cell proliferation and DNA synthesis of CHO-TRVb control cells, whereas it had little effect on TfR2-alpha-expressing CHO cells when measured by clonogenic and cell cycle analysis. In addition, CHO cells that express TfR2-alpha developed into tumors in nude mice whereas CHO control cells did not. In conclusion, TfR2 expression may be regulated by the cell cycle rather than cellular iron status and may support cell growth both in vitro and in vivo.     

Relationships between the cell cycle and the expression of c-myc and transferrin receptor genes during induced myeloid differentiation

We examined the relationship of cellular oncogene c-myc and transferrin receptor (TfR) gene expression to cell proliferation and cell cycle progression during myeloid differentiation in the HL-60 myeloid leukemia cell line. In order to determine levels of mRNA for these genes in HL-60 cells induced to differentiate along the myeloid pathway, RNA was isolated from HL-60 cells incubated with retinoic acid for 24 h and Northern blots were probed with labeled cDNAs for c-myc and TfR. c-myc mRNA decreased within 3 h of retinoic acid addition, and TfR mRNA decreased after 9 h; both mRNAs continued to decrease over 24 h. RNA was also isolated from HL-60 cells separated by centrifugal elutriation into cell cycle phases. TfR and c-myc cDNA probes hybridized equally to RNA from uninduced cells in all phases of the cell cycle. However, after 24 h incubation with the differentiation inducer retinoic acid, TfR mRNA was expressed substantially less in the G1 stage, whereas c-myc mRNA was still expressed equally in all cell cycle phases. These data indicate that, although TfR and c-myc expression are both associated with cell proliferation in the HL-60 line, TfR is down-regulated specifically in G1 upon induction of terminal differentiation whereas c-myc expression is disassociated from cell cycle control in these cells.     

Macrophage cell cycling: influence on Fc receptors and antibody-dependent phagocytosis

The influence of cell cycling on the density and binding properties of IgG2a Fc receptors and their associated antibody-dependent phagocytic activity was investigated with the P388D1 murine macrophage cell line. Unseparated macrophages and subpopulations of elutriated macrophages, enriched for cells in G1, S, and G2 + M phases were compared to detect possible differences in IgG2a-dependent phagocytosis. Suspensions of G2 + M phase cells were appreciably enhanced in phagocytic activity over G1-phase cells, which were less phagocytic than unseparated macrophage populations. An analysis of the binding of 125I-IgG2a myeloma protein disclosed that the IgG2a Fc receptor avidity remained essentially unchanged during cell cycle traverse, whereas the number of IgG2a Fc receptors more than doubled as cells cycled from G1 to G2 + M (1.5 X 10(5) vs 3.4 X 10(5) receptors per cell). With their increased size relative to G1 cells, and the resultant increase in receptor number, G2 phase cells should have more productive collisions with the antibody-coated target cells and greater phagocytic capacity.     

Immunogold labelling of tumour cells during NK/target cell interactions

Using a system of immunocolloidal gold labelling, we have monitored the expression and distribution of transferrin receptors (TfRs) within the K562 cell line, during NK/target cell interactions. An indirect method of immunolabelling was used to effectively immunolabel tumour cells without disrupting the natural effector:target interactions. Successful localization of TfRs demonstrates the potential of the described technique for discerning antigenic distribution of other cell:cell interactions. Immunolabelling has also provided a useful method for demonstrating receptor down-regulation within NK target cells, as a proposed cause of reduced receptor expression by TPA-treated cells. Following 30 and 60 min incubation periods with TPA, approximately 15 and 30%, respectively, of the gold/antibody complexes were relocated from the surface membrane to an intracellular location within endocytotic vesicles. The demonstration of receptor down-regulation is important as a proposed cause of TPA-induced tumour cell resistance to NK-mediated cytolysis.     

Canine and feline parvoviruses can use human or feline transferrin receptors to bind, enter, and infect cells

Canine parvovirus (CPV) enters and infects cells by a dynamin-dependent, clathrin-mediated endocytic pathway, and viral capsids colocalize with transferrin in perinuclear vesicles of cells shortly after entry (J. S. L. Parker and C. R. Parrish, J. Virol. 74:1919-1930, 2000). Here we report that CPV and feline panleukopenia virus (FPV), a closely related parvovirus, bind to the human and feline transferrin receptors (TfRs) and use these receptors to enter and infect cells. Capsids did not detectably bind or enter quail QT35 cells or a Chinese hamster ovary (CHO) cell-derived cell line that lacks any TfR (TRVb cells). However, capsids bound and were endocytosed into QT35 cells and CHO-derived TRVb-1 cells that expressed the human TfR. TRVb-1 cells or TRVb cells transiently expressing the feline TfR were susceptible to infection by CPV and FPV, but the parental TRVb cells were not. We screened a panel of feline-mouse hybrid cells for susceptibility to FPV infection and found that only those cells that possessed feline chromosome C2 were susceptible. The feline TfR gene (TRFC) also mapped to feline chromosome C2. These data indicate that cell susceptibility for these viruses is determined by the TfR.     

Downregulation of transferrin receptor surface expression by intracellular antibody

To deplete cellular iron uptake, and consequently inhibit the proliferation of tumor cells, we attempt to block surface expression of transferrin receptor (TfR) by intracellular antibody technology. We constructed two expression plasmids (scFv-HAK and scFv-HA) coding for intracellular single-chain antibody against TfR with or without endoplasmic reticulum (ER) retention signal, respectively. Then they were transfected tumor cells MCF-7 by liposome. Applying RT-PCR, Western blotting, immunofluorescence microscopy and immunoelectron microscope experiments, we insure that scFv-HAK intrabody was successfully expressed and retained in ER contrasted to the secreted expression of scFv-HA. Flow cytometric analysis confirmed that the TfR surface expression was markedly decreased approximately 83.4+/-2.5% in scFv-HAK transfected cells, while there was not significantly decrease in scFv-HA transfected cells. Further cell growth and apoptosis characteristics were evaluated by cell cycle analysis, nuclei staining and MTT assay. Results indicated that expression of scFv-HAK can dramatically induce cell cycle G1 phase arrest and apoptosis of tumor cells, and consequently significantly suppress proliferation of tumor cells compared with other control groups. For the first time this study demonstrates the potential usage of anti-TfR scFv-intrabody as a growth inhibitor of TfR overexpressing tumors.     

Transforming growth factors beta slow down cell-cycle progression in a murine interleukin-2 dependent T-cell line

Transforming growth factors beta (TGF-beta) inhibit the growth of a variety of cell types, including lymphocytes. The immunosuppressive effects of TGF-beta have been attributed to the interference of these molecules with the interleukin-2 (IL-2)-driven component of lymphocyte proliferation. In order to elucidate in more detail the effects of TGF-beta on IL-2-induced proliferation, we investigated the effects of porcine transforming growth factor beta 1 and 2 (pTGF-beta 1 and 2) on the IL-2-driven proliferation of a murine IL-2-dependent T-lymphocyte line (CTLL). The results showed that pTGF-beta 1 and 2 decreased 3H-thymidine incorporation in CTLL cells in a dose-dependent fashion (maximum decrease of 75-85%). Combined-time kinetic analysis of the effects of pTGF-beta on 3H-thymidine incorporation, cell growth, and cell-cycle distribution (monitored as DNA content distribution) revealed that, in the first 48 h of culture, pTGF-beta 1 increased the doubling time from 11.4 to 19.2 h without significantly affecting the cell-cycle distribution of CTLL cells. After 96 h of culture in the presence of pTGF-beta 1, cells started to accumulate in G0/G1, although at this time point 30% of the pTGF-beta 1-treated cells were still in S-G2/M. Furthermore, during the first 48 h, neither the expression of the 55 kd chain of the IL-2 receptor (IL-2R) nor the expression of the transferrin receptor (TfR) was affected by TGF-beta. After 72 h of culture in the presence of pTGF-beta 1, the expression of the IL-2R and TfR was decreased. The data suggest that in CTLL cells TGF-beta initially slows the progression of cells in all phases of cell cycle. In addition, the initial TGF-beta-mediated decrease of IL-2-induced 3H-thymidine incorporation and cell proliferation in CTLL cells is not due primarily to downregulation of the IL-2R and/or TfR.     

Desferoxamine blocks IL 2 receptor expression on human T lymphocytes

Thymidine uptake by PHA-stimulated human lymphocytes is reduced in the presence of 100 microM or greater concentrations of the iron-chelating agent desferoxamine (DF). We assessed expression of IL 2 receptor, 4F2 and Ia antigens, IL 2 production, and cell cycle progression by blood mononuclear cells (MNC) stimulated by PHA in the presence or absence of DF to determine whether the lack of T cell proliferation was a manifestation of inhibition of an earlier activation event. Tac antigen expression on PHA-stimulated MNC was inhibited by DF throughout 8 days of culture, and those cells which were positive had a low density of Tac antigen as compared with controls without DF. Expression of other activation antigens, 4F2 and Ia, was not impaired by DF. The supernatants of the DF-containing and control cultures contained equivalent IL 2 activity, as measured on the HT-2 cell line. Cell cycle analysis of these cultures shows that the addition of DF at the beginning of culture blocks most cells from undergoing G0 to G1 transition, whereas later addition of DF arrests the progression of the T cell blasts through the cell cycle. Separation of cells cultured with PHA and DF into Tac+ and Tac- subsets showed that progression from G0 to G1 was restricted to the former subset. These results suggest that interference with IL 2 receptor expression might contribute to the block in mitogen-induced proliferation caused by DF.     

Correlation between cell density, membrane fluidity, and the availability of transferrin receptors in Friend erythroleukemic cells

Undifferentiated Friend erythroleukemic cells (FL-cells) acquire membrane microviscosity (eta), in accord with the culture cell density. At low cell density eta (21 degrees) approximately 2.8 poise, whereas at confluency it increases to eta (21 degrees) approximately 5.3 poise. Concomitantly, the total number of available transferring receptors per cell decreases by about 80% upon increase in cell density. Modulation of membrane microviscosity, by artificial alteration of the membrane cholesterol level, mediates similar modulations of the availability of the transferrin receptors. The correlation between the availability of the transferring receptors and the membrane lipid fluidity may take part in the overt decrease in iron uptake by erythroid cells along the erythropoiesis pathway.     

c-myc expression is down-regulated by cell-cell and cell-extracellular matrix contacts in normal hepatocytes, but not in hepatoma cells.

Primary culture of adult rat hepatocytes resulted in marked increase of c-myc expression within a few hours. The high level of c-myc mRNA was maintained throughout culture on collagen-coated dishes, but decreased greatly with time during culture on collagen-gel or matrigel. Expression of c-myc was also down-regulated at high cell density. The decrease in its expression appeared closely related to inhibitions of DNA synthesis and cell spreading. In contrast, hepatoma H4TG cells showed a high level of c-myc expression which was not affected by culture on any extracellular matrices examined or by the cell density. These results suggest that up-regulation of expression of the c-myc gene is linked to G0 to G1 transition during cell cycle progression, which in normal hepatocytes is strictly regulated by cell-cell and cell-extracellular matrix interactions, but that this control mechanism is defective in malignant hepatic tumor cells.     

Heterogenous expression of a murine B16 melanoma-associated antigen correlates with cell cycle

Summary A murine monoclonal antibody (MM2-3C6) that reacts with a B16 murine melanoma-associated membrane antigen was used to study the relationship of antigen expression to the cell cycle. Dual-parameter flow cytometric measurements of membrane antigen and DNA revealed that antigen-positive cells were present throughout the cell cycle. Peak antigenic expression was noted during the late log phase of the cell growth curve with negligible antigen-negative population. The emergence of a distinct antigen-negative population (30%–40%) was noted in the late stationary phase. Cell cycle analysis indicated that the negative subpopulation was restricted to the G0/G1 phase, thus, demonstrating antigenic heterogeneity within the tumor cell population. Cell sorting was performed to analyze the origin of such heterogeneity. Following two sequential sortings, the antigen-negative cells became antigenic upon reculture. Again, at the late stationary phase, a distinct antigen-negative population (30%–40%) emerged. The sorted antigen-positive cells showed flow cytometric profiles identical to the sorted antigen-negative population upon reculture. Therefore, in this murine model, it appears that antigen expression is cell cycle dependent and such expression seems to be associated with proliferation.     

Human bone cell enzyme expression and cellular heterogeneity: correlation of alkaline phosphatase enzyme activity with cell cycle

Alkaline phosphatase, long implicated in biomineralization, is a feature of the osteoblast phenotype. Yet in cultured bone cells, only a fraction stain positive histochemically. To determine whether osteoblast enzyme expression reflects cellular heterogeneity with respect to cell cycle distribution or length of time in culture, the activities of alkaline phosphatase, tartrate-resistant and -sensitive acid phosphatases, and non-specific esterases were assayed kinetically and histochemically. In asynchronous subconfluent cultures, less than 15% of the cells stained positive and assayed activity was 0.04 IU/10(6) cells/cm2. After 1 week, the percent of alkaline phosphatase positive-staining cells increased 5-fold, while activity increased 10-fold. Non-specific esterases and tartrate-sensitive acid phosphatase were constitutive throughout time in culture, whereas tartrate-resistant acid phosphatase activity appeared after 2 weeks. Cell cycle analysis of human bone cells revealed a growth fraction of 80%, an S phase of 8.5 h, G2 + 1/2 M of 4 h, and a G1 of 25-30 h. In synchronous cultures induced by a thymidine-aphidicolin protocol, alkaline phosphatase activity dropped precipitously at M phase and returned during G1. A majority of the alkaline phosphatase activity lost from the cell surface at mitosis was recovered in the medium. Tartrate-sensitive acid phosphatase and non-specific esterase levels were relatively stable throughout the cell cycle, while tartrate-resistant acid phosphatase activity was not assayable at the density used in synchronous cultures. From these data, variations in alkaline phosphatase activity appear to reflect the distribution of cells throughout the cell cycle.