Albumin has no role in the uptake of copper by human fibroblasts

The mechanism of copper uptake by cells has been the subject of controversy for some time. This paper examines the possibility of a role for albumin in the uptake of copper by fibroblasts. Although the cells could accumulate copper from a copper-albumin complex, there was no evidence for either copper-albumin or albumin receptors on the cell surface. The possibility of a surface exchange mechanism for copper was examined. While copper uptake showed saturation with increasing concentrations of labelled copper-albumin, adding unlabelled copper to the incubation medium did not inhibit uptake. Adding albumin or histidine to the copper-albumin complex resulted in an inhibition of copper uptake. The results can only be explained by the cell taking up free copper from the incubation medium, with the albumin then releasing its copper to maintain the equilibrium between free and bound metal. Since, in vivo there is essentially no free copper in serum, it is concluded that albumin is most unlikely to play a role in the uptake of copper by fibroblasts.     

Physical-chemical model for the entry of water-insoluble compounds into cells. Studies of fatty acid uptake by the liver

The spontaneous transfer of water-insoluble substances from plasma to the interior of cells would involve a series of steps in which the substance of interest dissociates from albumin in plasma, enters the outer half of the plasma membrane of a cell, crosses the bilayer, and then dissociates from the inner half of the plasma membrane to enter cell cytosol and diffuses to sites of its metabolism. We have examined the behavior of long-chain fatty acids in the uptake process, assuming that none of these steps is facilitated by the cell during the entry of fatty acids into the liver. Comparison of the spontaneous rates for each individual step with rates of uptake of fatty acid by perfused liver leads to the conclusion that the uptake of fatty acids is not limited by kinetic factors but is determined instead by the equilibrium distribution (Keq) of fatty acids between albumin in plasma and the phospholipids of the plasma membrane. This idea was examined further by determining whether there was a relationship between the value for Keq and rates of uptake of a fatty acid and the pattern of kinetics for uptake. The data indicate that there is a linear relationship between Keq and the rate of uptake, that uptake rates can be predicted with a high degree of accuracy from thermodynamic data, and that the pattern of kinetics of uptake is compatible with the idea that the uptake rate is determined by the relative affinity of a fatty acid for albumin and membranes.     

The acute phase response to inflammation: the role of monokines in changes in liver glycoproteins and enzymes of glycoprotein metabolism

The role of monocyte derived factors in the acute phase response to inflammation is discussed. The kinetics of response of alpha 1-acid glycoprotein, sialyltransferase and albumin to a rat monokine preparation is described. There was an increase in synthesis of alpha 1-acid glycoprotein and sialyltransferase and a decrease in albumin synthesis following administration. However, the kinetics of response of sialyltransferase to the monokine was much slower than was found for the other two proteins. The possibility that sialyltransferase responds to a different monokine compared to the other acute phase proteins is discussed.     

Uptake of [(3)H]bilirubin in freshly isolated rat hepatocytes: role of free bilirubin concentration

Hepatocytic transport of physiological concentrations of unconjugated bilirubin (UCB) has not been determined in isolated liver cells. Initial uptake of highly purified [(3)H]UCB was measured in rat hepatocytes in the presence of human serum albumin at various free, unbound UCB concentrations, [UCB]. At [UCB]=42 nM (below aqueous solubility of 70 nM), uptake was strictly temperature dependent; this was much less evident at [UCB]=166 nM (supersaturated). At low, physiological UCB concentrations, specific UCB uptake showed saturative kinetics with an apparent K(m) of 41 nM, indicating carrier-mediated transport. With aqueous supersaturation, UCB entered hepatocytes mainly by passive diffusion.     

Transmembrane transport of fatty acids in the heart

Summary Although fatty acid uptake by the myocardium is rapid and efficient, the mechanism of their transmembrane transport has been unclear. Fatty acids are presented to the plasma membrane of cardiomyocytes as albumin complexes within the plasma. Since albumin is not taken up by the cells, it was postulated that specific high affinity binding sites at the sarcolemma may mediate the dissociation of fatty acids from the albumin molecules, before they are transported into the cells. In studies with a representative long-chain fatty acid, oleate, it was in fact shown that fatty acids bind with high affinity to isolated plasma membranes of rat heart myocytes revealing a K_D of 42 nM. Moreover, a specific membrane fatty acid-binding protein (MFABP) was isolated from these membranes. It had a molecular weight of 40 kD, an isoelectric point of 9.0, and lacked carbohydrate or lipid components. Binding to a specific membrane protein might represent the first step of a carrier mediated uptake process. Therefore, the uptake kinetics of oleate by isolated rat heart myocytes was determined under conditions where only cellular influx and not metabolism occurred. Uptake revealed saturation kinetics and was temperature dependent which were considered as specific criteria for a facilitated transport mechanism. For evaluation whether uptake is mediated by MFABP, the effect of a monospecific antibody to this protein on cellular influx of oleate was examined. Inhibition of uptake of fatty acids but not of glucose by the antibody to MFABP indicated the physiologic significance of this protein as transmembrane carrier in the cellular uptake process of fatty acids. Such a transporter might represent an important site for the metabolic regulation of fatty acid influx into the myocardium.     

The role of the kidney in lipid metabolism

PURPOSE OF REVIEW: Cellular uptake of plasma lipids is to a large extent mediated by specific membrane-associated proteins that recognize lipid-protein complexes. In the kidney, the apical surface of proximal tubules has a high capacity for receptor-mediated uptake of filtered lipid-binding plasma proteins. We describe the renal receptor system and its role in lipid metabolism in health and disease, and discuss the general effect of the diseased kidney on lipid metabolism. RECENT FINDINGS: Megalin and cubilin are receptors in the proximal tubules. An accumulating number of lipid-binding and regulating proteins (e.g. albumin, apolipoprotein A-I and leptin) have been identified as ligands, suggesting that their receptors may directly take up lipids in the proximal tubules and indirectly affect plasma and tissue lipid metabolism. Recently, the amnionless protein was shown to be essential for the membrane association and trafficking of cubilin. SUMMARY: The kidney has a high capacity for uptake of lipid-binding proteins and lipid-regulating hormones via the megalin and cubilin/amnionless protein receptors. Although the glomerular filtration barrier prevents access of the large lipoprotein particles to the proximal tubules, the receptors may be exposed to lipids bound to filtered lipid-binding proteins not associated to lipoprotein particles. Renal filtration and receptor-mediated uptake of lipid-binding and lipid-regulating proteins may therefore influence overall lipid metabolism. The pathological mechanisms causing the pronounced atherosclerosis-promoting effect of uremia may involve impairment of this clearance pathway.     

The role of albumin in the hepatic transport of bilirubin: studies in mutant analbuminemic rats

Bilirubin and other cholephilic organic anions are bound to albumin in the circulation; their hepatic uptake involves a carrier-mediated process. To investigate the possible role of serum albumin in the transhepatic transport of a cholephilic ligand, plasma clearance of radioactive bilirubin and its biliary excretion as well as its interaction with plasma proteins were compared between normal and mutant analbuminemic rats (NAR). With a tracer amount of 3H-labeled bilirubin, its plasma clearance and biliary excretion were comparable in both animal groups. However, the plasma clearance of a loading dose of the ligand was significantly increased and its biliary recovery was low in NAR as compared with normal animals. In accord with these findings in vivo, gel permeation chromatographic analysis revealed that the bilirubin binding capacity of serum proteins was significantly lower in NAR than in control animals. When bilirubin was administered to NAR as a mixture with equimolar albumin, its plasma disappearance was considerably decreased and its biliary recovery was increased. Similar effects were observed when albumin was replaced by an equimolar amount of glutathione S-transferases (ligandins). These observations indicate that, although ligand-protein interaction in the circulation is important for directing bilirubin to the plasma membranes of the hepatocyte, this mechanism is not specific for albumin.     

Uptake of copper from plasma proteins in cells where expression of CTR1 has been modulated

Plasma proteins rather than amino acid chelates are the direct sources of copper for mammalian cells. In continuing studies on the mechanisms by which albumin and transcuprein deliver copper and the potential involvement of CTR1, rates of uptake from these proteins and Cu-histidine were compared in cells with/without CTR1 knockdown or knockout. siRNA knocked down expression of CTR1 mRNA 60-85% in human mammary epithelial and hepatic cell models, but this had little or no effect on uptake of 1?μM Cu(II) attached to pure human albumin or alpha-2-macroglobulin. Mouse embryonic fibroblasts that did/did not express Ctr1 took up Cu(II) bound to albumin about as readily as from the histidine complex at physiological concentrations and by a single saturable process. Uptake from mouse albumin achieved a 2-4-fold higher Vmax (with a lower Km) than from heterologous human albumin. Maximum uptake rates from Cu(I)-histidine were >12-fold higher (with higher Km) than for Cu(II), suggesting mediation by a reductase. The presence of cell surface Cu(II) and Fe(III) reductase activity responding only slightly to dehydroascorbate was verified. Excess Fe(III) inhibited uptake from albumin-Cu(II). Ag(I) also inhibited, but kinetics were not or un-competitive. In general there was little difference in rates/kinetics of uptake in the Ctr1+/+ and -/- cells. Endocytosis was not involved. We conclude that plasma proteins deliver Cu(II) to homologous cells with greater efficiency than ionic copper at physiological concentrations, probably through the mediation of a Steap Cu(II)-reductase, and confirm the existence of an additional copper uptake system in mammalian cells.     

A megalin-like receptor is involved in protein endocytosis in the midgut of an insect (Bombyx mori, Lepidoptera)

The mechanism responsible for fluorescein isothiocyanate (FITC)-albumin internalization by columnar cells in culture obtained from the midgut of Bombyx mori larvae was examined by confocal laser scanning microscopy. Protein uptake changed over time, and it appeared to be energy dependent, since it was strongly reduced by both low temperatures and metabolic inhibitors. Labeled albumin uptake as a function of increasing protein concentration showed a saturation kinetics with a Michaelis constant value of 2.0 +/- 0.6 microM. These data are compatible with the occurrence of receptor-mediated endocytosis. RT-PCR analysis and colocalization experiments with an anti-megalin primary antibody indicated that the receptor involved was a putative homolog of megalin, the multiligand endocytic receptor belonging to the low-density lipoprotein receptor family, responsible for the uptake of various molecules, albumin included, in many epithelial cells of mammals. This insect receptor, like the mammalian counterpart, required Ca(2+) for albumin internalization and was inhibited by gentamicin. FITC-albumin internalization was clathrin mediated, since two inhibitors of this process caused a significant reduction of the uptake, and clathrin and albumin colocalized in the intermicrovillar areas of the apical plasma membrane. The integrity of actin and microtubule organization was essential for the correct functioning of the endocytic machinery.     

Measurement of the free concentration of octylphenol in biological samples with negligible depletion-solid phase microextraction (nd-SPME): analysis of matrix effects

A negligible depletion-solid phase microextraction (nd-SPME) method is presented to measure free concentrations of octylphenol in biological samples. Potential confounding factors, such as matrix effects, are studied as well. Fouling of the fibre appears to occur, but it does not seem to reduce or enhance the measured uptake of octylphenol. In the setup applied here, without any agitation, it has also been found that there is a large effect of protein presence on the kinetics of octylphenol uptake. In addition, an apparent affinity constant of octylphenol for bovine serum albumin was determined.     

Design of compounds having enhanced tumour uptake,using serum albumin as a carrier—part II. In vivo studies

In the present in vivo study the uptake kinetics of radioiodinated albumin were determined in normal organs, and tumours of rats using sequential scintigraphy. Rat serum (RSA) was radioiodinated either directly at a tyrosine residue (d-RSA), or indirectly at a residualizing marker tagged to the albumin (rm-RSA). These labelling procedures did not alter the kinetics of labelled albumin, as shown by blood disappearance curves. Directly labelled albumin was shown to have tumour uptake. Residualizing markers like tyramine-cellobiose (TCB), tyramine-deoxysorbitol (TDS) and aminonaphthaltyrimide-deoxysorbitol (ANTDS) are metabolically inert. After the intracellular degradation of the albumin carrier the TCB-, TDS- and ATNDS-residues accumulate in the lysosomes, particularly those of tumour cells. It was able to be demonstrated that residualizing-marker tagged albumin-bound radioactivity was five times higher after 72 h than the tumour radioactivity after use of directly labelled RSA. These data found support when whole-body retention of directly labelled RSA, and residualizing marker-RSAs, were determined. After 72 h, 60% of ¹³¹I bound to RSA directly had been excreted, compared to only 25% of the activity attached indirectly to RSA with a residualizing marker. Whole-body autoradiography of rats injected with directly labelled RSA, or residualizing marker-RSA, support these results. Most of the radioactivity of directly labelled RSA was excreted within 24 h, whereas labelled residualizing marker-RSAs were also stored in tumour and liver tissue. ANTDS bound to RSA allows fluorescence microscopy. Cryosections of tumours from rats preinjected 10 min and 24 h with ANTDS-RSA before dissection, demonstrated that the fluorescence is localized on and in tumour cells. This indicates that cellular uptake of the marker takes place. Fluorescence was not observed in muscle tissue. This appears to suggest that the albumin uptake is greater in tumours than in normal tissue, and that it is metabolized in the tumour cells.     

The role of acetyl coenzyme A: butyrate coenzyme A in the transferase uptake of butyrate by isolated membrane vesicles of Escherichia coli

The acetyl CoA:butyrate CoA transferase catalyzes the translocation of butyrate in membrane vesicles prepared from a strain of Escherichia coli which is depressed for the acetoacetate degradation operon. Butyrate accumulated in the membranes as butyryl CoA. The role of the transferase in uptake is supported by the following observations: (i) uptake is stimulated by acetyl CoA; (ii) the solubilized CoA transferase and uptake exhibit K_mS for butyrate, pH optima and levels inhibition by N-ethylmaleimide that are virtually identical; (iii) significant amounts of the CoA transferase are found associated with the membranes and uptake is rapidly inhibited by butyryl CoA and acetate, the products of the CoA transferase-catalyzed reaction. The fact that butyrate uptake did not exhibit saturation kinetics with increasing concentrations of acetyl CoA suggested that the transferase is not localized on the outer surface of the membrane. The level of free butyrate in the vesicles, the fact that butyrate uptake exhibited saturation kinetics with increasing concentrations of butyrate, and the observation that radioactivity was not rapidly lost from the vesicles following addition of butyryl CoA or acetate to incubation mixtures indicated that butyrate is translocated rather than trapped by the CoA transferase.     

Silicon uptake in diatoms revisited: a model for saturable and nonsaturable uptake kinetics and the role of silicon transporters

The silicic acid uptake kinetics of diatoms were studied to provide a mechanistic explanation for previous work demonstrating both nonsaturable and Michaelis-Menten-type saturable uptake. Using (68)Ge(OH)(4) as a radiotracer for Si(OH)(4), we showed a time-dependent transition from nonsaturable to saturable uptake kinetics in multiple diatom species. In cells grown under silicon (Si)-replete conditions, Si(OH)(4) uptake was initially nonsaturable but became saturable over time. Cells prestarved for Si for 24 h exhibited immediate saturable kinetics. Data suggest nonsaturability was due to surge uptake when intracellular Si pool capacity was high, and saturability occurred when equilibrium was achieved between pool capacity and cell wall silica incorporation. In Thalassiosira pseudonana at low Si(OH)(4) concentrations, uptake followed sigmoidal kinetics, indicating regulation by an allosteric mechanism. Competition of Si(OH)(4) uptake with Ge(OH)(4) suggested uptake at low Si(OH)(4) concentrations was mediated by Si transporters. At high Si(OH)(4), competition experiments and nonsaturability indicated uptake was not carrier mediated and occurred by diffusion. Zinc did not appear to be directly involved in Si(OH)(4) uptake, in contrast to a previous suggestion. A model for Si(OH)(4) uptake in diatoms is presented that proposes two control mechanisms: active transport by Si transporters at low Si(OH)(4) and diffusional transport controlled by the capacity of intracellular pools in relation to cell wall silica incorporation at high Si(OH)(4). The model integrates kinetic and equilibrium components of diatom Si(OH)(4) uptake and consistently explains results in this and previous investigations.     

Kinetics of adsorption of proteins at interfaces: role of protein conformation in diffusional adsorption

To elucidate the role of protein conformation in the kinetics of adsorption at interfaces, seven structural intermediates of bovine serum albumin were prepared and their adsorption at the air/water interface was studied. Molecular area calculations indicated two distinct molecular processes, the first being the creation of an area, delta A1, for anchoring the molecule during the initial phase of adsorption and the second being the delta A2 cleared during subsequent reorientation and rearrangement of adsorbed molecules at the interface. The delta A1 values for all the albumin intermediates were the same, indicating that the initial work pi delta A1 needed to anchor the molecule at the interface was independent of solution conformation of the protein. Unlike delta A1, delta A2 exhibited a bell-shaped relationship with the extent of refolded state of the intermediates. Calculation of diffusion coefficients indicated that greater the unfolded state of the albumin intermediate, the greater was the diffusion coefficient. It is shown that the simple diffusion theory is inadequate to explain quantitatively the kinetics of protein adsorption. Specific, conformation-dependent, solute-solvent and solute-interface interactions also seem to influence the kinetics of adsorption of proteins.     

Modulatory role of eicosanoids in vascular changes during the preovulatory period in the rat

Previous studies have demonstrated the involvement of eicosanoids (prostaglandins and hydroxyperoxides, including leukotrienes) in ovulation in several mammalian species. In this study, the role played by eicosanoids in the vascular changes that occur in the immediate preovulatory period after human chorionic gonadotropin (hCG) stimulation was examined in the rat. Changes in the ovarian uptake of two iodinated proteins were examined 30 minutes after i.v. injection of 125I-bovine serum albumin (BSA, Mr = 68,000) and 125I-alpha 2-macroglobulin (alpha 2M, Mr = 750,000). Uptake was measured during 30 min, 0, 3, 6, and 9 h after induction of ovulation by an i.p. injection of human chorionic gonadotropin (hCG, 10 IU). hCG enhanced the uptake of both iodinated proteins, with peak uptake values at 6 and 9 h. Intra-bursal injections of an ovulation inhibiting dose (0.5 mg/bursa) of indomethacin-a cycooxygenase inhibitor-and nordihydroguaiaretic acid (NDGA), esculetin, or caffeic acid--inhibitors of lipoxygenase--concomitantly with hCG attenuated the action of the hormone on 125I-BSA uptake. Indomethacin and esculetin were without effect on the uptake of alpha 2M. Ovarian and follicular blood flow was measured using 113Sn-microspheres. hCG increased ovarian and follicular blood flow with the most pronounced effect at the early time of 1.5 h. Indomethacin and NDGA did not attenuate this action of hCG. Accordingly, ovarian vascular resistance was reduced by hCG at 1.5, 6, and 9 h post-hCG, respectively, and indomethacin and NDGA had no significant effects. We suggest that one way in which eicosanoids are involved in follicular rupture is by their modulation of vascular permeability as revealed by uptake of the protein marker albumin.     

Mechanism of copper transport from plasma to hepatocytes

The effects of plasma components on the kinetics of copper transport by rat hepatocytes were examined in an attempt to determine how copper is mobilized from plasma for uptake by the liver. Specific protein-facilitated transport was indicated by saturation kinetics, competition by related substrates, and similar kinetic parameters for uptake and efflux. For copper uptake, Km = 11 +/- 0.6 microM and Vmax = 2.7 +/- 0.6 nmol Cu/(min X mg protein). Zinc is a competitive inhibitor of copper uptake, and copper competes for zinc uptake. Copper efflux from preloaded cells is biphasic. The kinetic parameters for the initial rapid phase are similar to the parameters for uptake. Copper transport by hepatocytes is strictly passive. A variety of metabolic inhibitors have no effect on uptake and initial rates are solely dependent on extracellular-intracellular concentration gradients. Albumin markedly inhibits copper uptake by a substrate removal mechanism, and histidine facilitates albumin-inhibited copper uptake. The active species that delivers copper to hepatocytes under conditions of excess albumin and excess histidine is the His2Cu complex. Experiments with [3H]His2 64Cu showed that the transported species is free ionic copper. The kinetic parameters of copper transport by hepatocytes isolated from the brindled mouse model of Menkes' disease are normal. However, these cells show a decreased capacity to accumulate copper on prolonged incubation. An intracellular metabolic defect seems to be involved.     

The effect of chemical treatments of albumin and orosomucoid on rate of clearance from the rat bloodstream and rate of pinocytic capture of rat yolk sac cultured in vitro.

Portions of a 125I-iodinated bovine serum albumin preparation were exposed to freezing, acetic acid (pH 3.5, 3.0 or 2.5), urea or formaldehyde, and the effect of these treatments on the rates of pinocytic uptake by yolk sacs from 17.5-day-pregnant rats cultured in vitro and of clearance from the rat bloodstream were studied. Uptake of albumin by the yolk sac was followed by rapid release of [125I]iodo-L-tyrosine into the culture medium. Similarly clearance of albumin in vivo was accompanied by the appearance of trichloroacetic acid-soluble radioactivity in the bloodstream. In both systems the rates of uptake of modified albumin preparations formed a series: formaldehyde or urea greater than acetic acid greater than freezing. The increased rates of uptake of modified albumin preparations could not be ascribed to the formation of aggregates nor, in the yolk-sac system, to an increase in the rate of pinosome formation. It is concluded that the various treatments to which the albumin was subjected increase to varying degrees the affinity of the albumin molecule for binding sites on that region of the plasma membrane from which pinocytic vesicles are formed. Some comparable experiments with native and desialylated human orosomucoid indicate that the rat yolk-sac epithelial cells do not possess the recognition system for uptake of asialoglycoproteins that exists on the surface of hepatic parenchymal cells.     

The role of the liver macrophage system in decreasing the immune complex level of the blood during adaptation to periodic hypoxia]

It has been established that adaptation to intermittent hypoxia in altitude chamber considerably increases the capacity of hepatic macrophagal systems (MFS) to uptake Indian ink particles from the blood as well as immunoglobulin labelled with fluorescein isothiocyanate. There is simultaneous catabolism of labelled albumin in hepatic MFS. It has been suggested that the increased C3b-component of complement system in blood observed in adaptation to hypoxia plays a substantial role in the activation of hepatic MFS. The role of hepatic MFS activation in reducing the number of circulating immune complexes is emphasized as well as its role in therapeutic effect of adaptation in allergic diseases.     

Caveolae-deficient endothelial cells show defects in the uptake and transport of albumin in vivo.

The role of endothelial cell caveolae in the uptake and transport of macromolecules from the blood-space to the tissue-space remains controversial. To address this issue directly, we employed caveolin-1 gene knock-out mice that lack caveolin-1 protein expression and caveolae organelles. Here, we show that endothelial cell caveolae are required for the efficient uptake and transport of a known caveolar ligand, i.e. albumin, in vivo. Caveolin-1-null mice were perfused with 5-nm gold-conjugated albumin, and its uptake was followed by transmission electron microscopy. Our results indicate that gold-conjugated albumin is not endocytosed by Cav-1-deficient lung endothelial cells and remains in the blood vessel lumen; in contrast, gold-conjugated albumin was concentrated and internalized by lung endothelial cell caveolae in wild-type mice, as expected. To quantitate this defect in uptake, we next studied the endocytosis of radioiodinated albumin using aortic ring segments from wild-type and Cav-1-null mice. Interestingly, little or no uptake of radioiodinated albumin was observed in the aortic segments from Cav-1-deficient mice, whereas aortic segments from wild-type mice showed robust uptake that was time- and temperature-dependent and competed by unlabeled albumin. We conclude that endothelial cell caveolae are required for the efficient uptake and transport of albumin from the blood to the interstitium.     

The effects of an antibody to the rat transferrin receptor and of rat serum albumin on the uptake of diferric transferrin by rat hepatocytes

The role of high-affinity specific transferrin receptors and low-affinity, non-saturable processes in the uptake of transferrin and iron by hepatocytes was investigated using fetal and adult rat hepatocytes in primary monolayer culture, rat transferrin, rat serum albumin and a rabbit anti-rat transferrin receptor antibody. The intracellular uptake of transferrin and iron occurred by saturable and non-saturable mechanisms. Treatment of the cells with the antibody almost completely eliminated the saturable uptake of iron but had little effect on the non-saturable process. Addition of albumin to the incubation medium reduced the endocytosis of transferrin by the cells but had no significant effect on the intracellular accumulation of iron. The maximum effect of rat serum albumin was observed at concentrations of 3 mg/ml and above. At a low incubation concentration of transferrin (0.5 microM), the presence of both rat albumin and the antibody decreased the rate of iron uptake by the cells to about 15% of the value found in their absence, but to only 40% when the diferric transferrin concentration was 5 microM. These results confirm that the uptake of transferrin-bound iron by both fetal and adult rat hepatocytes in culture occurs by a specific, receptor-mediated process and a low-affinity, non-saturable process. The low-affinity process increases in relative importance as the iron-transferrin concentration is raised.