Phorbol esters and calcium ionophores inhibit internalization and accelerate recycling of receptors in macrophages

Substrate-bound fibronectin enhances scavenger receptor activity of macrophages by calcium signaling

We have previously found that ability of mouse macrophages to bind and take up oxidized low-density lipoprotein (oxLDL) through scavenger receptors is significantly enhanced when the cells are plated on fibronectin (FN)-coated culture substrates. Here, the mechanisms of the enhancement of the scavenger receptor activity by the substrate-bound FN was investigated using thioglycollate-induced mouse peritoneal macrophages. A Ca(2+) channel blocker diltiazem and a calmodulin inhibitor W-7 reduced the scavenger receptor activity of the macrophages plated on FN-coated substrate to the level of the cells plated on uncoated substrate, as assessed by oxLDL binding, while the scavenger receptor activity of the macrophages on uncoated substrate was little affected. Similarly, FN-induced enhancement of the scavenger receptor activity assessed by oxLDL uptake was selectively inhibited by Ca(2+) channel blockers (diltiazem, nifedipine, verapamil) and calmodulin inhibitors (W-7, trifluoperazine). Intracellular free Ca(2+) level of the macrophages was increased, depending on extracellular Ca(2+), when plated on FN-coated substrate. This increase in the Ca(2+) level was inhibited by diltiazem and RGD-containing peptides present in cell adhesive region of FN. Like the substrate-bound FN, Ca(2+) ionophore A23187 enhanced the scavenger receptor activity of binding and taking up of oxLDL. These results indicate that substrate-bound FN enhances scavenger receptor activity of macrophages by increasing channel-dependent Ca(2+) influx. A microtubule disruptor, colchicine, and an actin filament disruptor, cytochalasin B, inhibited the FN-induced enhancement of the scavenger receptor activity, suggesting that these cytoskeletal structures are required for transmission of the adhesion signal of FN. The number of the scavenger receptors was found to increase by 1.4-fold upon adhesion signal of FN. We suggest that substrate-bound FN increases the number of the macrophage scavenger receptors as a result of induction of Ca(2+) influx and causes increased accumulation of oxLDL within the cells, rendering the cells more susceptible to conversion into foam cells.

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.

Cultured human fibroblasts contain a large pool of precursor beta 1-integrin but lack an intracellular pool of mature subunit

Previous work has shown the presence of an important intracellular pool of beta 1-integrin subunit in human skin fibroblasts as detected with monoclonal antibody DH12 [De Strooper, B., Van der Schueren, B., Jaspers, M., Saison, M., Spaepen, M., Van Leuven, F., Van den Berghe, H. & Cassiman, J. J. (1989) J. Histochem. Cytochem. 37,299-307]. To analyze this more quantitatively, a radioimmunoassay with radioiodinated monoclonal antibody was developed. The total amount of specific binding sites for monoclonal antibody DH12 on skin fibroblasts was between 0.8-1.5 x 10(6)/cell. After permeabilizing the cells with digitonin, a threefold increase in specific binding was observed, which suggested that about 60% of the total amount of beta 1-subunit was localized intracellularly. From pulse/chase experiments, it was deduced that an important pool of precursor subunit, as defined by its sensitivity to endoglycosidase treatment, existed in fibroblasts. Since in steady-state-labeling conditions, at least three to four times more precursor than mature subunit was immunoprecipitated with monoclonal antibody DH12, we suggested that the intracellular pool of beta 1-integrin subunit is mainly precursor pool. This precursor pool contains a degradation compartment and a maturation compartment. Other investigators have found evidence for a recirculating pool of mature integrin in Chinese hamster ovary cells. Therefore, the presence of a recirculating pool of integrin in human fibroblasts was also considered. The data obtained with mAb DH12 showed that less than 10% of the surface pool of integrin was internalized by endocytosis. Since, however, cross linking of beta 1-integrins with polyclonal antibodies leads to rapid endocytosis of most of the integrin, it remains possible that the quantitatively small effect was actually an artefact induced by the divalent mAb. We conclude that the intracellular pool of beta 1-integrins observed in our previous studies consists of precursor and that in skin fibroblasts no mature beta 1-integrin is available intracellularly for rapid quantitative modulations at the cell surface.

Regulation of ANF receptor internalization: involvement of extracellular calcium

Receptor mediated internalization of 125I-ANF (99-126) and the underlying mechanism was studied in PC12 cells. Phosphorylation of PC12 cell plasma membrane proteins at 0 degrees C or 37 degrees C was not altered in presence of ANF (99-126) or c-ANF (4-23). Exposure of cells to phorbol 12-myristate 13-acetate (PMA, 100 ng/ml) did not alter the endocytic rate or extent of 125I-ANF (99-126) internalization. When cells were treated with a combination of PMA and the calcium ionophore A23187, internalization was not stimulated. Incubation with A23187 (10 microM) alone decreased 125I-ANF (99-126) internalization by 22% in Ca2+ containing medium. Cell surface binding increased 10% in the presence of Ca2+ compared to Ca2+ free medium, irrespective of the presence of A23187. Ca2+ appears to play an important role in the binding of ANF to the receptor and initiation of ligand-receptor complex internalization. Activation of protein kinase C or receptor phosphorylation is not an essential step in initiating ANF receptor internalization.

Inhibition of late endosome-lysosome fusion: studies on the mechanism by which isotonic-K+ buffers alter intracellular ligand movement

Incubation of alveolar macrophages or hepatocytes in media in which Na+ is replaced by K+ ("isotonic-K buffer") inhibited the movement of internalized ligand from late endosomes to lysosomes (Ward et al.: Journal of Cell Biology 110:1013-1022, 1990). In this study we investigate the mechanism responsible for the isotonic-K+ block in movement of ligand from late endosomes to lysosomes. We observed that iso-K+ inhibition of endosome-lysosome fusion is not unique to alveolar macrophages or hepatocytes but can be seen in a variety of cell types including J774 and Hela cells. The inhibition in intracellular ligand movement was time dependent with the maximum change occurring after 60 minutes. Once established the inhibition resulted in a prolonged and apparently permanent decrease in vesicle movement. Cells were able to recover from the effects of iso-K+ buffers over a time course of 5-10 minutes when placed back in Na(+)-containing media. The effect of iso-K+ buffers was independent of intracellular pH changes and appeared to involve cell swelling. When cells were incubated in iso-K+ buffers under conditions in which cell volume changes were reduced, intracellular ligand movement approached normal levels. Such conditions included replacing Cl- with the less permeant anion gluconate, and by addition of sucrose to isotonic-K+ buffers. Analysis of the mechanism by which changes in cell volume could alter intracellular movement ruled out changes in cyclic nucleotides, Ca2+, or microtubules. These results suggest that changes in cell shape or volume can alter intracellular transport systems by novel routes.

Growth factor-dependent regulation of transferrin receptor in proliferating and quiescent macrophages

Transferrin receptor (TfR) expression in a population of murine macrophages was investigated during the colony-stimulating factor-1 (CSF-1)-induced proliferation and quiescence. Depletion of CSF-1 from the culture medium of bone marrow cell-derived macrophages (BMM) resulted in a simultaneous decrease in the total (cell surface + intracellular) amount of TfR and complete cessation of proliferating activity [( 3H]thymidine incorporation). The addition of CSF-1 to quiescent BMM resulted in a bimodal increase in surface TfR activity. A rapid but transient twofold increase only on the cell surface due to changes in the cycling of TfR was followed by a steady increase of total cellular TfR due to de novo synthesis. A similar transient increase in surface TfR was also induced by another hemopoietic colony-stimulating factor, GM-CSF, which is mitogenic for BMM. IL-3, which did not stimulate the clonal growth of these cells, failed to modulate surface TfR. In contrast to its effect on the cycling rate of TfR in quiescent cells, CSF-1 had little effect on the TfR distribution on proliferating BMM as well as on the J774 cells (a macrophage-like tumor cell line) despite the latter expressing high levels of CSF-1 receptor. This study showed that (i) cell surface modulation by growth factor is a function of state of cellular proliferation, and (ii) rapid changes in the cell surface distribution of TfR result from changes in its cycling rates.

Effect of volume and pH on surface receptor number in macrophages

Incubation of rabbit alveolar macrophages in hypo-osmotic solutions transiently increases cell volume and inhibits membrane internalization, resulting in an increase in surface receptor number. Since recent reports suggest that hypo-osmotic treatment decreases intracellular pH, and that reduced pH inhibits receptor internalization, pH was measured in hypo-osmotically treated macrophages. We found that cells incubated in iso-osmotic solutions of pH less than 7.2 exhibited a decrease in intracellular pH upon exposure to hypo-osmotic solutions, while cells in iso-osmotic solutions of pH greater than 7.2 had an increase in pH upon exposure to hypo-osmotic solutions. The relative increase in surface receptor number was unaffected by the initial pH or by the direction of change in pH. Incubation of cells in high K+/low Na+ hypotonic buffers induced a persistent increase in cell volume and surface receptor number. Cell volume and surface receptor number fell to baseline values after restoration of isotonicity by the addition of hypertonic sucrose. These manipulations had little effect on intracellular pH. We conclude that the inhibition of membrane internalization observed in cells exposed to hypo-osmotic solutions is independent of changes in intracellular pH. The inhibition of internalization observed in this system may be due directly to forces produced as a consequence of cell swelling.

Possible involvement of a 95-kDa protein phosphorylation in phorbol 12-myristate 13-acetate-induced suppression of zymosan phagocytosis in guinea pig macrophages

Recently, we characterized a surface antigen (Z-1) of guinea pig macrophages by monoclonal anti-Z-1 antibody. The Z-1 antigen consists of two different polypeptide chains; alpha (140 kDa) and beta (95 kDa). This antigen is closely correlated with the phagocytic activity of the cells for zymosan and presumably functions as a receptor for zymosan. In the present study, the effect of phorbol 12-myristate 13-acetate (PMA) on the function of Z-1 was examined. Incubation of ortho-[32P]phosphate-labeled macrophages with PMA greatly increased the phosphorylation of the beta subunit of Z-1 but not that of the alpha subunit. Optimal phosphorylation was observed when cells were incubated with 300 ng/ml of PMA for 60-120 min. The PMA-induced phosphorylation was markedly suppressed by treatment of the macrophages with H-7, an inhibitor of protein kinase C. A chemotactic peptide, N-formyl-Met-Leu-Phe (fMLP) also caused phosphorylation of the beta subunit. Unlike PMA, fMLP maximized the phosphorylation within 30 s. Purified Z-1 was an excellent substrate for the exogenously added protein kinase C only in the presence of both Ca2+ and phosphatidylserine. H-7 completely inhibited the in vitro phosphorylation. These data suggest that the beta subunit of Z-1 is phosphorylated by protein kinase C. The phosphorylation of Z-1 by PMA and fMLP coincided with inhibition of zymosan phagocytosis. A linear relationship was obtained between the level of phosphorylation of Z-1 and the degree of inhibition of zymosan phagocytosis induced by PMA. Thus, the results suggest that zymosan uptake is negatively regulated by protein kinase C-mediated phosphorylation of the beta subunit of Z-1.

Effect of hypo-osmotic incubation on membrane recycling

Incubation of alveolar macrophages in hypo-osmotic media causes a time-and temperature-dependent increase in the number of surface receptors for three different ligands. Exposure of cells to solutions of 210 mOsM or less, at 37 degrees C but not at 0 degree C, resulted in an increase in the number of surface receptors for diferric transferrin, alpha-macroglobulin-protease complexes, and mannose-terminated glycoproteins. Upon media dilution at 37 degrees C, surface receptor number reached a maximum within 5 min and returned to near-normal values by 30 min. The increase in surface receptor number was the result of a decrease in the rate of internalization of receptors, either occupied or unoccupied. The rate of receptor exteriorization was unaltered by hypo-osmotic incubation of cells. The rate of fluid-phase pinocytosis was also inhibited upon incubation in hypo-osmotic solution. In experiments in which both receptor-mediated endocytosis and fluid phase pinocytosis were measured on the same samples, inhibition of both processes occurred with the same kinetics and to a similar extent. The rate of receptor-mediated endocytosis recovered to normal rates after 60 min in hypo-osmotic solutions, whereas the rate of fluid phase pinocytosis did not recover to the same extent.

Regulatory volume decrease in alveolar macrophages: cation loss is not correlated with changes in membrane recycling

Alveolar macrophages regain their normal volume after swelling in hypo-osmotic solutions. This process, termed regulatory volume decrease (RVD), is initiated 3-5 minutes after exposure of cells to hypo-osmotic solutions, and by 30 min, near-normal volumes are attained. Volume decrease does not occur at 0 degrees C or in solutions in which Na+ has been replaced by K+, or Cl- by the impermeant anion gluconate. These results, as well as direct measurement of intracellular cations, indicate that decreases in cell volume result primarily from the loss of K+ and Cl- and are similar to RVD in lymphocytes. Kinetic analysis of cation loss, both by directly measuring changes in intracellular cation content and by assaying rubidium efflux, showed that cation loss occurred immediately upon media dilution. The rate of cation loss fit first-order kinetics and preceded both the initiation of volume decrease and the maximum increase in surface receptor number. These results suggest that the cation transporters responsible for RVD are located at the cell surface and that regulation of activity is not dependent on alterations in membrane movement.