Subcellular localization of ferritin and iron taken up by rat hepatocytes.

The subcellular localization of ferritin and its iron taken up by rat hepatocytes was investigated by sucrose-density-gradient ultracentrifugation of cell homogenates. After incubation of hepatocytes with 125I-labelled [59Fe]ferritin, cells incorporate most of the labels into structures equilibrating at densities where acid phosphatase and cytochrome c oxidase are found, suggesting association of ferritin and its iron with lysosomes or mitochondria. Specific solubilization of lysosomes by digitonin treatment indicates that, after 8 h incubation, most of the 125I is recovered in lysosomes, whereas 59Fe is found in mitochondria as well as in lysosomes. As evidenced by gel chromatography of supernatant fractions, 59Fe accumulates with time in cytosolic ferritin. To account for these results a model is proposed in which ferritin, after being endocytosed by hepatocytes, is degraded in lysosomes, and its iron is released and re-incorporated into cytosolic ferritin and, to a lesser extent, into mitochondria.     

Endocytic pathways and time sequence of lysosomal transfer of macromolecules in cultured mouse peritoneal macrophages

Summary A double-labeling protocol was used to study endocytic pathways and lysosomal transfer of exogenous macromolecules in cultured mouse peritoneal macrophages. After pulse-chase labeling of lysosomes with horseradish peroxidase (visualized cytochemically), the cells were exposed to native, anionic ferritin for 0–45 min at 37° C and then analysed by transmission electron microscopy. The results show that ferritin binds to the plasma membrane, accumulates in coated pits, and is rapidly taken up in small, smooth-surfaced endocytic vesicles. The latter carry the ferritin molecules directly to lysosomes, recognized by their peroxidase labeling, or fuse with each other to form larger endocytic vacuoles (endosomes) which in turn fuse with and empty their content into lysosomes. The first signs of transfer of ferritin into the lysosomes were seen after 5–10 min of exposure and after 25–30 min most of the lysosomes were labeled. Union of ferritin-labeled and other lysosomes was also noted, suggesting that the contents of the lysosomes were spread within the lysosomal compartment by fusion-fission processes. It is concluded that a multiplicity of structures is involved in the uptake and intracellular transport of exogenous macromolecules in macrophages and that the time sequence of lysosomal transfer of the interiorized material is highly variable.     

A morphological study of ferritin synthesis in macrophages with ingested ferric hydroxide-potassium polyvinyl sulfate complexes

A ferric hydroxide-polyvinyl sulfate colloidal solution (Fe-PVS), prepared by mixing potassium polyvinyl sulfate (PVSK) and ferric hydroxide colloidal solution was used to study ferritin synthesis in rat peritoneal macrophages. The colloidal particles had spherical electron opaque ferric hydroxide cores with diameters of about 250 nm surrounded by radially arranged fibrous PVS molecules. They also had strong negative electric charges. Fe-PVS particles injected into the peritoneal cavity were taken up by the macrophages then disintegrated rapidly. In the phagolysosomes the electron opaque ferric hydroxide cores of Fe-PVS were denuded of their PVS frames then decomposed into small 5-6 nm granules 24 to 48 h after injection. These small granules were released from the lysosomes into the hyaloplasm and the myelin figures were found in the lysosomal vacuoles. No reaccumulation of granules in lysosomes was found even 3 months later. The intracellular distribution of ferritin in macrophages demonstrated by the immunocytochemical method showed a pattern similar to that of the small granules formed by the disintegration of Fe-PVS. This means that in rat peritoneal macrophages that contain ingested Fe-PVS particles ferritin first is synthesized in phagolysosomes by the ferric hydroxide cores that conjugate with apoferritin or protein subunits then they are dispersed into the cytoplasm. Two possible pathways for the biosynthesis of ferritin are discussed.     

Single cell assay with an automated capillary microinjection system

An automated capillary microinjection system with computer-controlled positioning of the cells and of the capillary, and its applications and advantages, is described. The system is easy in handling and manipulation. About 1500 injections are possible in 1 h, with high reproducibility. In cytoplasmic and nuclear injections more than 90 and 85% of the cells are successfully injected. Using FITC-dextran at a concentration of 0.5% as a fluorescently labeled coinjection marker, 99% of the cells can be retrieved in culture medium even 48 h after injection. The coordinates of the cells are stored in the computer and accuracy in statistical evaluation of experiments is improved in comparison to the manual techniques. Methods for preparation and handling of glass capillaries were developed resulting in reproducible form and significantly reduced clogging rate. The improved characteristics offered by this system are demonstrated in studies leading to the confirmation of existence of an mRNA inhibiting DNA synthesis in cells. Functional screening by cell injections of cDNA libraries and of size-fractionated mRNA molecules can be performed efficiently with the automated microinjection system.     

Pathways in the binding and uptake of ferritin by hepatocytes

The binding and uptake of rat liver ferritin by primary cultures of rat liver hepatocytes was studied in order to assess the relative importance of saturable, high-affinity pathways and nonspecific processes in the incorporation of the protein by the cells. To minimize artifacts, ferritin not subjected to heat treatment and labeled in vivo with 59Fe was used. Binding to cell membranes was estimated from incubations performed at 4 degrees C. After 2 h, when a steady state in cell-associated ferritin had been achieved, approx. 4-10(4) binding sites per cell were observed, with an affinity constant for ferritin of 1 x 10(9) M-1. At 37 degrees C, the maximal uptake from these sites was 1.3 x 10(5) ferritin molecules/cell per h. For ferritin molecules bearing an average of 2400 iron atoms, this uptake amounts to 5 x 10(6) iron atoms/cell per min. Half-maximal uptake was achieved at a ferritin concentration, or KM1, of 3 x 10(-9) M. Although uptake rates at least a thousand times greater could be achieved by binding to the much larger number of low-affinity sites, the apparent KM2 for such 'nonspecific' uptake was 4 x 10(-7) M. At ferritin concentrations up to 2 nM, at least 90% of ferritin bound and taken up by hepatocytes involves saturable, high-affinity sites, presumably true ferritin receptors.     

Receptor-mediated endocytosis of alpha 2-macroglobulin and transferrin in rat caput epididymal epithelial cells in vitro

The endocytic activity of epithelial cells from the rat epididymis in vitro has been examined by following the uptake of tracer compounds conjugated to proteins. Transferrin-gold and alpha 2-macroglobulin-gold were taken up initially in coated pits, internalized and sequestered into tubular-vesicular structures, multivesicular bodies and, in the case of alpha 2-macroglobulin, into lysosomes. Uptake could be prevented by an excess of unlabeled protein. Studies using 125I-alpha 2-macroglobulin and 125I-transferrin also showed that the uptake of these proteins was specific and could be displaced with increasing amounts of unlabeled protein. In addition, binding of 125I-transferrin to cells was saturable at 4 degrees C. These studies indicate that transferrin and alpha 2-macroglobulin are taken up by receptor-mediated endocytosis. In contrast, a fluid phase marker, bovine serum albumin-gold (BSA-gold), was initially taken up predominantly in uncoated caveolae rather than coated pits, and could not be displaced with excess BSA. By virtue of their charge, polycationized ferritin and unlabeled colloidal gold were taken up and internalized by adsorptive endocytosis, a pathway which is similar to fluid phase endocytosis. The uptake and internalization of alpha 2-macroglobulin and transferrin differed in a number of respects. Uptake and internalization of alpha 2-macroglobulin but not of transferrin was dependent on extracellular calcium. Only alpha 2-macroglobulin was transferred into lysosomes, whereas transferrin was recycled to the cell surface. Although the proton ionophore, monensin, and the transglutaminase inhibitor, dansylcadaverine, did not stop uptake and internalization of either alpha 2-macroglobulin or transferrin, they did prevent the transfer of alpha 2-macroglobulin to lysosomes.     

Quantitative analysis of immunogold labelling for ferritin in liver from control and iron-overloaded rats

Summary The distribution of ferritin antigenicity in control and iron-loaded rat hepatocytes was investigated with an immunogold-ferritin antibody technique. Antibody to horse spleen ferritin showed immunoreactivity as determined by dot blotting with immunogold/silver staining with purified rat liver ferritin but not with rat haemosiderin. The initial site of ferritin degradation was studied by analysing the density of gold labelling in the cytosol and lysosomes in combination with pre-embedding acid phosphatase cytochemistry.Immunoreactive ferritin was present in the cytosol, cytosolic clusters and lysosomes of normal hepatocytes. After iron-loading, the labelling density increased over tenfold in parenchymal cell cytosol with a smaller increase in Kupffer cells. Ferritin clusters contained substantially more immunoreactive ferritin than equivalent areas of lysosomes or cytosol. Analysis of the labelling density in hepatocyte lysosomes showed that, despite a striking increase in iron content, one-quarter of the lysosomes showed less immunolabelled ferritin than the cytosol. The existence of a wide range of ferritin labelling densities in the lysosomes with a large proportion unlabelled suggests that the ferritin protein shell is not degraded at a significant rate either in the cytosol or in clusters but only after incorporation into lysosomes.     

The uptake of cationized ferritin by guinea-pig gall bladderin vitro

Summary Tissue pieces of guinea-pig gall bladder were grownin vitro for up to ten days. Over this period at different intervals, specimens were exposed to cationized ferritin in culture medium for 1 h and then grown in ferritin free medium for up to 24 h. Other specimens were grown in culture medium containing cationized ferritin for up to 24 h. Both treatments produced a similar morphological sequence. Electron microscopy at all intervals studied showed the cationized ferritin was first bound by the apical cell membrane, clumped and internalized in large 400 nm vesicles. It was then carried to lysosomes in the region of the Golgi apparatus. Within 1 h, the marker was exocytosed in clumps into the lateral intercellular space, accumulating against the basement membrane in a roughly regular approximately 60 nm array. This pathway of cationized ferritin through the gall bladder epithelium is the same as that followedin vivo although the time taken was shorterin vitro.     

Endocytosis of native and cationized ferritin by intralobular duct cells of the rat parotid gland

Summary The ability of the intralobular ducts of the rat parotid gland to take up protein from the lumen was examined after retrograde infusion of native and cationized ferritin. At high concentrations (3–10 mg/ml), cells of both intercalated- and striated ducts avidly internalized the tracers. No differences were noted in the mode of uptake or fate of native or cationized ferritin. Large, apical ferritin-containing vacuoles up to 5 m in size were present in cells of the intercalated ducts after infusion for 15 min. Small, smooth-surfaced spherical or flattened vesicles and tubules containing ferritin were also observed, often in association with the large vacuoles. Ferritin uptake increased with increasing infusion time, up to 1 h. Uptake by the striated ducts was less consistent than by the intercalated ducts, and occurred mainly in small vesicles and tubules. Secondary lysosomes became labeled with ferritin in both cell types. Ferritin was not observed in the Golgi saccules, nor was it discharged from the cells at the basolateral surfaces. At low concentrations (0.3–1 mg/ml), uptake was reduced, especially by cells of intercalated ducts, and differences were noted in the behavior of the two tracers. Cationized ferritin was internalized mainly into vesicles and tubules of cells of striated ducts; little uptake of native ferritin occurred at low concentrations. These results demonstrate that the ductal cells of the salivary glands are capable of luminal endocytosis of foreign proteins. They also suggest that in addition to modifying the primary saliva by electrolyte reabsorption and secretion, and secretion of various glycoproteins, the ductal cells are able to reabsorb proteins secreted by the acinar cells.     

Association of ferritin with liver cell membrane fractions.

Following intraperitoneal injection of rats with a large dose of ferric ammonium citrate containing ⁵⁹Fe, some 35 to 50% of the dose was deposited in the liver within the first 1 to 4 h. Almost all of the deposited iron could be precipitated with a ferritin antiserum from a homogenate of liver heated to 75 °C, but only half of this was precipitable when the unheated homogenate was treated with antiserum. The remainder of the ferritin iron was made available to the antiserum by treatment with deoxycholate, and was therefore presumed to be associated with membranous components of the cell.Subcellular fractionation of the liver following administration of ⁵⁹Fe-labeled ferric ammonium citrate showed that most of the radioactivity deposited within the first 4 h was equally divided between the cell sap and a light microsome (membrane-rich) fraction. Ferritin in this latter fraction was made available to antibody following deoxycholate treatment. The liver microsome fraction of the young rat contains little unavailable ferritin, but with aging there is an accumulation of ferritin in the microsomal fraction which is unavailable to antibody until the membrane is removed.It is suggested that at least part of the injected iron salt is taken up by pinocytotic vesicles and transferred to ferritin within this fraction, possibly followed by release of some of this ferritin into the cell sap.     

Membrane retrieval in epithelial cells of isolated thyroid follicles.

Follicles from rat and pig thyroid glands were isolated by digestion with collagenase. The epithelial cells of isolated follicles maintain their structural and functional polarity as shown by incorporation of 3H-leucine and autoradiography. To trace the fate of surface membrane, isolated follicles were opened, stimulated with thyrotropin and incubated for various time intervals with cationized ferritin (CF), uncharged dextran, native ferritin (NF), and latex spheres (0.5 mum in diameter) which were either pre-coated with CF or added together with CF. Uncharged dextran and native ferritin did not bind to the luminal cell membrane, were taken up in small amounts and accumulated in lysosomes; anionic NF was not found in Golgi cisternae in contrast to uncharged dextran which occassionally reached a few Golgi stacks. CF bound rapidly and in clusters to the luminal plasmalemma, preferentially to coated pits, was taken up by endocytosis, accumulated in lysosomes after 5 min and reached the Golgi cisternae after 30 min. Latex spheres were taken up by engulfment through fusion of microvilli and reached the lysosomes. CF particles coating the latex spheres may detach at this station and reach the Golgi cisternae. The findings show that the route of small tracers depends on the charge of the tracer, in agreement with results obtained by Farquhar [8]. Vesicles carrying NF can be traced to lysosomes only, whereas vesicles containing uncharged dextran or - more conspicuously -CF also fuse with Golgi membranes. Large tracers (latex beads) reach only the lysosomes, but CF taken up with them may move to Golgi cisternae.     

Capillary Microinjection into Protoplasts and Intranuclear Localization of Injected Materials

By a direct microinjection through pressurized glass micropipettes,we injected fluorescent Lucifer Yellow, berberine and berberine-boundDNA into protoplasts isolated from cultured Euphorbia milliicells and from tobacco mesophyll cells. The protoplasts to beinjected were held by a holding pipette with which the cytoplasmor nucleus of the protoplasts could be oriented with referenceto the tip of the injection pipette. Upon microinjection ofa berberine-bound DNA, the nucleus and intranuclear organelles,possibly including nucleolus, specifically exhibited yellowfluorescence due to berberine. This provides a direct evidencethat DNA molecules can be microinjected into the intranuclearcompartment of the protoplasts. The injected protoplasts survivedthe capillary microinjection. (Received August 6, 1984; Accepted November 12, 1984)     

Release of iron from ferritin requires lysosomal activity

How ferritin-Fe becomes available for cell functions is unknown. Our previous studies with rat hepatoma cells indicated ferritin had to be degraded to release its Fe. In these studies, we investigated whether this occurs in other cell types and whether lysosomes are required. Release of ferritin-Fe was induced with desferoxamine (DFO) in ⁵⁹Fe-preloaded hepatoma, Caco2, and erythroid K562 cells and measured by rocket immunoelectrophoresis and autoradiography. The half-lives for ferritin-⁵⁹Fe and protein were parallel (23, 16, and 11 h for the hepatic, Caco2, and K562 cells, respectively). Co-treatment with 180 µM Fe, leupeptin, chymostatin, or chloroquine markedly decreased rates of ferritin-Fe release and ferritin degradation. Lactacystin had no effect except for a small one in erythroid cells. Fractionation of hepatoma cell lysates on iodixanol gradients showed rapid depletion of cytosolic ferritin by DFO treatment but no accumulation in lysosomes. We conclude that regardless of cell type, release of Fe from ferritin occurs mainly through lysosomal proteolysis. degradation; proteasomes     

Recovery of surface membrane in anterior pituitary cells. Variations in traffic detected with anionic and cationic ferritin

Cells dissociated from rat anterior pituitaries were incubated with native or cationized ferritin (CF) to trace the fate of surface membrane. Native ferritin, which did not bind to the cell surface, was taken up in small amounts by bulk-phase endocytosis and was found increasingly (over 1-2 h) concentrated in lysosomes. CF at 100-fold less concentrations bound rapidly to the cell membrane, was taken up by endocytosis in far greater amounts, and within 15-60 min was found increasingly within multiple stacked Golgi cisternae, around forming secretion granules, and within elements of GERL, as well as within lysosomes. The findings demonstrate that the fate of the tracer--and presumably also that of the surface membrane--varies with the same molecule differing only in net charge: vesicles carrying anionic ferritin (net negative charge) fuse only with elements of the lysosomal system whereas those carrying CF (net positive charge) can fuse not only with elements of the lysosomal system, but also with elements along the secretory pathway (Golgi cisternae and condensing granules) as well.     

Microinjection of living adherent cells by using a semi-automatic microinjection system

Testing in vitro is an alternative to animal experimentation. The capillary pressure microinjection technique is a supporting technology for efficient in vitro testing. The main benefit of the technique is the possibility of injecting large molecules into a single living cell. The ultimate goal of the research discussed in this paper is to increase the cell survival rate in capillary pressure microinjection. A method to reliably evaluate cell survival rate is therefore needed. A three-phase evaluation process is presented in this paper. The first phase determines the success rate of the injection capillary to penetrate the cell membrane. The second phase studies the success rate of delivering the injection substance inside the cell, while the third phase studies cell survival after the microinjection. In addition to the three-phase evaluation process, this paper describes the initial results of penetration and injection tests performed by using a semi-automatic capillary pressure microinjection system developed by the research group. Three adherent cell lines, namely, retinal pigment epithelial cells, MCF-7 human breast cancer cells and SH-SY5Y neuroblastoma cells, were used in the experiments. The results of the penetration tests show that the average success rate of penetrating the cell membrane using the micromanipulator was 87%. The goal of the injection tests was to demonstrate the successful microinjection of living cells and to study the injection success rate. Fluorescein dextran was injected into MCF-7 cells, and preliminary results showed an injection success rate of 49%. In the survival tests, the neuronal cells were microinjected with KCl. During long-term observation after the microinjection, the microinjected cells first decreased their adhesion to the plate, but later adhered to the bottom of the plate and even grew some dendrites. In the next phase of the study, more tests will be performed in order to obtain a statistically reliable value for the survival rate.     

Both subunits of rat liver ferritin are regulated at a translational level by iron induction.

A few hours after administering iron to rats, liver ferritin synthesis increases several fold. However, Northern blot analysis with cDNA probes for ferritin light (L) and heavy (H) subunit mRNAs failed to show an increase in total population of either messenger. Cytoplasmic distribution of ferritin messages was therefore investigated in control and iron administered rats killed at 3.5 hours. The liver post-mitochondrial supernatant was fractionated on a sucrose gradient to separate polyribosomes, monosomes, ribosomal subunits and cell sap. RNA extracted from each fraction and analyzed using Northern blotting showed that 65% of the total mRNA population for each subunit was present in the cell sap of control rats, presumably as mRNP particles since ribosomal RNA was absent from this fraction. After iron administration, these reserves of free mRNA were recruited onto the polysomes, reducing the free mRNA pool to 15% of the total. We interpret this to be due to activation of blocked ferritin messages on entry of iron into the cell.     

Intracellular segregation of asialo-transferrin and asialo-fetuin following uptake by the same receptor system in suspended hepatocytes

Asialo-transferrin and asialo-fetuin are both taken up into suspended hepatocytes by the asialo-glycoprotein receptor and with similar kinetics (Tolleshaug, H., Chindemi, P. and Regoeczi, E. (1981) J. Biol. Chem. 265, 6526-6528). However, the intracellular fate of the two ligands differ. Asialo-fetuin is carried to the lysosomes and degraded. Internalized asialo-transferrin is recycled with the receptors back to the cell surface, from which it may be released by calcium chelators. In the current studies, we fractionated cell homogenates in sucrose density gradients in order to trace the pathways taken by asialo-transferrin and asialo-fetuin within the cells. More than one-half of the intracellular asialo-transferrin sedimented within a novel kind of 'light' endosomes which were recovered at 1.11 g/ml in sucrose gradients. When cells were fractionated 6 min after the addition of trace concentrations of 125I-asialo-fetuin and 131I-asialo-transferrin, their intracellular distributions were found to be roughly similar. After 24 min their distributions were clearly disparate, relatively more asialo-fetuin being recovered in a peak of heavy endosomes at 1.15 g/ml. The ligand molecules in this part of the gradient (e.g., asialo-fetuin) were delivered to the lysosomes to be degraded, while the material in the lighter peak was degraded much more slowly. The data indicate that asialo-fetuin and asialo-transferrin enter a light endosome fraction immediately after receptor-mediated endocytosis. Subsequently, they are separated; the asialo-transferrin remains receptor-bound and is returned to the cell surface, while the asialo-fetuin is transferred to endosomes of density 1.15 g/ml and is eventually degraded in the lysosomes.     

STUDIES ON PROTEIN UPTAKE BY ISOLATED TUMOR CELLS : I. Electron Microscopic Evidence of Ferritin Uptake by Ehrlich Ascites Tumor Cells

Ferritin, added to the incubation medium of ascites tumor cells, was used as an electron microscopic marker to study the uptake of large protein molecules by morphologically intact cells. A definite uptake could be detected after 1 hour of incubation in Tyrode bicarbonate solution containing 0.04 to 13.3 mg ferritin/ml. Ferritin was found in a variety of membrane-surrounded structures, suggesting that pinocytesis and related membrane movements are occurring under physiological conditions and can account for the penetration of intact macromolecules into isolated tumor cells. Supplementation of the medium with serum albumin (33 mg/ml) increased the average amount of ferritin per cell and per pinocytotic structure. Ferritin was strongly adsorbed by fragments of lysed cells, which were readily taken up by intact cells. Besides its role as carrier, this debris appeared to stimulate membrane movements. Only rare examples were found to suggest the release of ferritin from the pinocytotic structures into the cytoplasm. Thus, the disintegration of such structures cannot be considered an obvious step towards a rapid metabolic utilization of protein by the cell. Particles of colloidal gold presented to the cell under the same conditions were not taken up to any significant extent, thus providing good evidence for a selective ingestion of particles of comparable sizes.     

Monensin and chloroquine inhibit transfer to lysosomes of endocytosed macromolecules in cultured mouse peritoneal macrophages

The effects of the Na+/H+ ionophore monensin and the weak base chloroquine on lysosomal uptake of endocytosed macromolecules were studied in cultured mouse peritoneal macrophages using horseradish peroxidase (HRP) and ferritin as exogenous tracers. The lysosomes were first loaded with HRP using a pulse-chase protocol. The cells were then exposed to ferritin for 30 to 120 min, either in control medium or in medium containing 3 microM monensin or 50 microM chloroquine. Semiquantitative electron microscopic analyses indicated that the uptake of ferritin into HRP-labeled lysosomes was inhibited in the drug-treated cells, and that the tracer particles accumulated in endosomes. At the same time the volume density of the endosomes was increased, fourfold by monensin and threefold by chloroquine; with the latter drug there was also an increase in lysosome volume density. Further, both drugs decreased the rate of endocytosis as measured biochemically, but not in proportion to the reduction of lysosomal ferritin uptake. After withdrawal of the drugs, cell morphology returned to normal and transfer of ferritin from endosomes to HRP-labeled lysosomes was resumed. The recovery was more rapid and complete in monensin-treated than in chloroquine-treated cells. On the basis of these findings and earlier investigations demonstrating that monensin and chloroquine both raise the pH in acid cell compartments, it is suggested that the transfer of soluble and not only membrane-bound macromolecules from endosomes to lysosomes is modulated by the pH in these organelles.