Effects of monensin on the synthesis, transport, and intracellular degradation of proteoglycans in rat ovarian granulosa cells in culture

OUP accepted manuscript

Host carbohydrates, or glycans, have been implicated in the pathogenesis of many bacterial infections. Group A Streptococcus (GAS) is a Gram-positive bacterium that readily colonises the skin and oropharynx, and is a significant cause of mortality in humans. While the glycointeractions orchestrated by many other pathogens are increasingly well-described, the understanding of the role of human glycans in GAS disease remains incomplete. Although basic investigation into the mechanisms of GAS disease is ongoing, several glycointeractions have been identified and are examined herein. The majority of research in this context has focussed on bacterial adherence, however, glycointeractions have also been implicated in carbohydrate metabolism; evasion of host immunity; biofilm adaptations; and toxin-mediated haemolysis. The involvement of human glycans in these diverse avenues of pathogenesis highlights the clinical value of understanding glycointeractions in combatting GAS disease.

Drug Library Screening for the Identification of Ionophores That Correct the Mistrafficking Disorder Associated with Oxalosis Kidney Disease

Primary hyperoxaluria is the underlying cause of oxalosis and is a life-threatening autosomal recessive disease, for which treatment may require dialysis or dual liver-kidney transplantation. The most common primary hyperoxaluria type 1 (PH1) is caused by genetic mutations of a liver-specific enzyme alanine:glyoxylate aminotransferase (AGT), which results in the misrouting of AGT from the peroxisomes to the mitochondria. Pharmacoperones are small molecules with the ability to modify misfolded proteins and route them correctly within the cells, which may present an effective strategy to treat AGT misrouting in PH1 disorders. We miniaturized a cell-based high-content assay into 1536-well plate format and screened ~4200 pharmacologically relevant compounds including Food and Drug Administration, European Union, and Japanese-approved drugs. This assay employs CHO cells stably expressing AGT-170, a mutant that predominantly resides in the mitochondria, where we monitor for its relocation to the peroxisomes through automated image acquisition and analysis. The miniaturized 1536-well assay yielded a Z' averaging 0.70 ± 0.07. Three drugs were identified as potential pharmacoperones from this pilot screen, demonstrating the applicability of this assay for large-scale high-throughput screening.

Accumulation of Glycosaminoglycans in Radiation-induced Muscular Fibrosis

The content and biosynthesis of glycosaminoglycans (GAGs) were studied in the pig thigh muscle after acute local gamma-irradiation. Seven months following irradiation, the muscular tissue next to the irradiation cone was replaced by severe mutilating fibrosis delimited by an intermediary perifbrotic zone. Fibrosis, perifibrotic tissue and normal muscle, were sampled and incubated with [3H]glucosamine and [35S]sulphate, and GAGs were isolated following pronase digestion. Results showed a parallel increase of collagen and GAG content in perifibrotic and fibrotic tissues. Sulphated GAGs, heparan sulphate and dermatan sulphate were preferentially accumulated in fibrotic tissue, while the hyaluronic acid content increased only slightly. Synthesis of sulphated GAGs was more elevated in fibrotic tissue than in perifibrotic zone as compared with normal muscle. Seven months after irradiation well-developed fibrotic tissue continued to synthesize and to accumulate extracellular matrix macromolecules, indicating the invasive aspect of post-irradiation fibrosis.

Hepatic uptake and metabolism of phosphatidylcholine associated with high density lipoproteins

BACKGROUND

Phosphatidylcholine (PC) is the predominant phospholipid associated with high density lipoproteins (HDL). Although the hepatic uptake of cholesteryl esters from HDL is well characterized, much less is known about the fate of PC associated with HDL. Thus, we investigated the uptake and subsequent metabolism of HDL-PC in primary mouse hepatocytes.

METHODS AND RESULTS

The absence of scavenger receptor-BI resulted in a 30% decrease in cellular incorporation of [(3)H]PC whereas [(3)H]cholesteryl ether uptake was almost completely abolished. Although endocytosis is not involved in the uptake of cholesteryl esters from HDL, we demonstrate that HDL internalization accounts for 40% of HDL-PC uptake. Extracellular remodeling of HDL by secretory phospholipase A(2) significantly enhances HDL lipid uptake. HDL-PC taken up by hepatocytes is partially converted to triacylglycerols via PC-phospholipase C-mediated hydrolysis of PC and incorporation of diacylglycerol into triacylglycerol. The formation of triacylglycerol is independent of scavenger receptor-BI and occurs in extralysosomal compartments.

CONCLUSIONS AND GENERAL SIGNIFICANCE

These findings indicate that HDL-associated PC is incorporated into primary hepatocytes via a pathway that differs significantly from that of HDL-cholesteryl ester, and shows that HDL-PC is more than a framework molecule, as evidenced by its partial conversion to hepatic triacylglycerol.

Glycan antagonists and inhibitors: a fount for drug discovery

Glycans, the carbohydrate chains of glycoproteins, proteoglycans, and glycolipids, represent a relatively unexploited area for drug development compared with other macromolecules. This review describes the major classes of glycans synthesized by animal cells, their mode of assembly, and available inhibitors for blocking their biosynthesis and function. Many of these agents have proven useful for studying the biological activities of glycans in isolated cells, during embryological development, and in physiology. Some are being used to develop drugs for treating metabolic disorders, cancer, and infection, suggesting that glycans are excellent targets for future drug development.

Recognition, Cointernalization, and Recycling of an Avian Riboflavin Carrier Protein in Human Placental Trophoblasts

Absorption of riboflavin (RF) across membrane barriers is essential to cellular oxidation reduction processes. Riboflavin carrier protein (RCP), a 37-kDa secretory protein, is proposed to play an important role in RF absorption, although information on the mammalian ortholog remains unclear. This study alludes to the existence of a mammalian RF carrier protein and further characterizes its carrier role and fate using avian RCP in human placental trophoblast (BeWo), another mammalian cell line, monkey kidney (COS-1), and the avian control, chicken hepatic (LMH/2A) cells. The presence of RCP and its involvement in RF internalization was analyzed by immunofluorescence and immunobinding assays using chicken RCP (cRCP) antibodies. In the presence of anti-cRCP, cellular RF uptake is significantly decreased (5% of control) in BeWo cells. Kinetic analyses of intracellular accumulation of (125)I-cRCP revealed a J(max) and K(m) of 28.56 +/- 2.70 pmol/mg protein/min and 142.43 +/- 82.16 nM, respectively, in BeWo cells and 75.14 +/- 7.6 pmol/mg protein/min and 104.37 +/- 23.96 nM in the species-specific control, LMH/2A cells. Subcellular fractionation studies revealed colocalization of both radiolabeled RF and cRCP within endosomal and lysosomal fractions, further elucidating RCP's role in trafficking RF through the cell. Following intracellular release of RF from the carrier complex, the protein is either subject to lysosomal breakdown or is conserved via recycling mechanisms for continued RF sequestration and uptake. In summary, mammalian placental trophoblasts exhibit specific carrier protein dependence that sequesters and essentially mediates RF internalization via the proposed receptor-mediated endocytic pathway.

Internalization and stepwise degradation of heparan sulfate proteoglycans in rat hepatocytes

Intracellular transport and degradation of membrane anchored heparan sulfate proteoglycans (HSPGs) were studied in cultured rat hepatocytes labeled with [35S]sulfate and [3H]glucosamine. Pulse chase experiments showed that membrane anchored HSPGs were constitutively transported to the cell surface after completion of polymerization and modification of the glycosaminoglycan chains in the Golgi apparatus. The intact HSPGs had a relatively short residence time at the cell surface and in non-degrading compartments (T(1/2) approximately 2-3 h), while [35S]sulfate labeled degradation products were found in lysosomes, and to a lesser extent in late endosomes. These degradation products which were free heparan sulfate chains with little or no protein covalently attached, were approximately half the size of the original glycosaminoglycan chains and were the only degradation intermediate found in the course of HSPG catabolism in these cells. In cells incubated in the presence of the microtubule perturbant vinblastine, or in the presence of the vacuolar ATPase inhibitor bafilomycin A1, and in cells incubated at 19 degrees C, the endocytosed HSPGs were retained in endosomes and no degradation products were detected. Disruption of lysosomes with glycyl-phenylalanine 2-naphthylamide (GPN) revealed a GPN resistant degradative compartment with both intact and partially degraded HSPGs. This compartment probably corresponds to late endosomes. Treatment of hepatocytes with the thiol protease inhibitor leupeptin inhibited the final degradation of the protein moiety of the HSPGs. The protein portion seems to be degraded completely before the glycosaminoglycan chains are cleaved. The degradation of the glycosaminoglycan chains is rapid and complete with one observable intermediate.

Cell surface heparan sulfate proteoglycans control the response of renal interstitial fibroblasts to fibroblast growth factor-2

BACKGROUND

While the progression of renal disease to end stage is strongly correlated with tubulointerstitial changes, the control of the fibrotic process within the interstitium is poorly understood. Basic fibroblast growth factor (FGF-2) has been implicated as a major growth factor involved in fibroblast activation and extracellular matrix synthesis. Furthermore, in many cells, the activity of FGF-2 is controlled by a low-affinity but high-capacity interaction with heparan sulfate (HS) proteoglycans (PGs), such as members of the syndecan family. These molecules are likely to be central to the control of interstitial fibrosis, but as yet, there has been no characterization of their synthesis by interstitial cells.

METHODS

The expression of HSPG on the surface of NRK 49F fibroblasts was demonstrated by immunohistochemistry and by metabolic labeling with [(35)S]-sulfate. HSs were characterized by specific enzymatic digestion, size exclusion chromatography, and anion exchange chromatography. The mRNA for syndecan 1 through syndecan 4 in the fibroblasts was detected by semiquantitative reverse transcription-polymerase chain reaction. Fibroblast proliferation was measured by the MTT assay.

RESULTS

Immunohistochemistry and [(35)S]-sulfate-labeling demonstrated that renal fibroblasts expressed HSPGs on their surface. Furthermore, enzymatic removal of these HS (but not chondroitin sulfate) glycosaminoglycan (GAG) chains, or inhibition of GAG sulfation, abolished the proliferative response of both NRK cells and primary human cortical fibroblasts to FGF-2 but not to platelet-derived growth factor. The addition of conditioned medium, containing HS-GAG fragments, restored the proliferative response to FGF-2, confirming the specificity of the interaction. Finally, the mRNA for all four syndecans was detected in the fibroblasts, and that for syndecan 1 in particular was up-regulated by FGF-2.

CONCLUSIONS

The present study demonstrates that the expression of cell surface HSPG was essential for the proliferation of renal fibroblasts in response to FGF-2, and therefore may play a major role in the development and persistence of a proliferating phenotype during interstitial nephritis.

Heparan sulfate chains with antimitogenic properties arise from mesangial cell-surface proteoglycans

Heparan sulfate (HS) chains accumulate in both the medium and the cell layer of mesangial cell cultures. When given in fresh medium to quiescent cultures at naturally occurring concentrations, they suppress entry into the cell cycle and progression to DNA synthesis. We have attempted to identify the proteoglycan (PG) source of the antimitogenic HS chains from mesangial cell layers (HS(c)) and medium (HS(c)). When cells were labeled for 16 hours with [35S]sulfate, 25% of the label was found in intracellular HS chains and 5% in extracellular HSPGs. Cell-surface HSPGs accounted for the remaining 70% of the label associated with cell-layer HS and were released by either trypsin or 2% Triton X-100. About 20% of this cell-surface fraction was released by treatment with phosphatidylinositol-specific phospholipase C (PI-PLC), and probably represents glypican-like PG; glypican mRNA was present in the cells. The remainder of this fraction could be incorporated into liposomes, indicating the presence of hydrophobic transmembrane regions suggestive of syndecans. Upon purification and deglycosylation, an antiserum to rat liver HSPGs that reacts primarily with syndecan-2 showed a strong signal corresponding to this protein and three weaker bands that may represent additional syndecans. mRNAs for syndecan-1, -2, and -4 were present in the cultures. Syndecan-1 and -2 mRNAs were increased 30 minutes after stimulation of quiescent rat mesangial cells (RMCs) with serum. Heparin, HS(c), and HS(m) all prevented this increase. Syndecan-4 mRNA was not affected by serum, heparin, or HS. In pulse-chase experiments, the amount of 35S appearing in the cellular protein-free HS fraction was accounted for almost entirely by cell-surface PGs, as matrix-associated label was a minor contribution at the end of the pulse-labeling. The appearance of [35S]HS in cell extracts was unaffected by phospholipase C treatment, indicating that turnover of the newly labeled syndecan fraction is the source of the antimitogenic HS chains.

Turnover of heparan sulfate depends on 2-O-sulfation of uronic acids

To study how the pattern of sulfation along a heparan sulfate chain affects its turnover, we examined heparan sulfate catabolism in wild-type Chinese hamster ovary cells and mutant pgsF-17, defective in 2-O-sulfation of uronic acid residues (Bai, X., and Esko, J. D. (1996) J. Biol. Chem. 271, 17711-17717). Heparan sulfate from the mutant contains normal amounts of 6-O-sulfated glucosamine residues and iduronic acid and somewhat higher levels of N-sulfated glucosamine residues but lacks any 2-O-sulfated iduronic or glucuronic acid residues. Pulse-chase experiments showed that both mutant and wild-type cells transport newly synthesized heparan sulfate proteoglycans to the plasma membrane, where they shed into the medium or move into the cell through endocytosis. Internalization of the cell-associated molecules leads to sequential endoglycosidase (heparanase) fragmentation of the chains and eventual lysosomal degradation. In wild-type cells, the chains begin to degrade within 1 h, leading to the accumulation of intermediate (10-20-kDa) and small (4-7-kDa) oligosaccharides. Mutant cells did not generate these intermediates, although internalization and intracellular trafficking of the heparan sulfate chains appeared normal, and the chains degraded with normal kinetics. This difference was not due to defective heparanase activities in the mutant, since cytoplasmic extracts from mutant cells cleaved wild-type heparan sulfate chains in vitro. Instead, the heparan sulfate chains from the mutant were relatively resistant to degradation by cellular heparanases. These findings suggest that 2-O-sulfated iduronic acid residues in heparan sulfate are important for cleavage by endogenous heparanases but not for the overall catabolism of the chains.

Protection by glycine against chemical ischemia produced by cyanide in cultured hepatocytes

The killing of cultured hepatocytes by cyanide accelerated phospholipid metabolism, with a reduction in cytoplasmic pH, but did not accelerate proteolysis. Alkalinization of the cytoplasm by monensin, a protonsodium exchange ionophore, enhanced the loss of viability and acceleration of phospholipid metabolism caused by cyanide. Thus, acidification of the cytoplasm appears to protect against the toxic effects of cyanide. Glycine reduced the killing of hepatocytes, concomitant with reduced phospholipid metabolism. The protective effect of glycine neither enhanced the reduction in cytoplasmic pH nor prevented the depletion of adenosine triphosphate (ATP) by cyanide. The mechanism of the protection exerted by glycine against chemical ischemia can be attributed neither to changes in cytoplasmic pH nor to the prevention of ATP depletion, but appears to be due to other mechanisms that have yet to be identified.

Characterization and hormonal modulation of anticoagulant heparan sulfate proteoglycans synthesized by rat ovarian granulosa cells

Anticoagulant heparan sulfate proteoglycans endow the vascular endothelium with antithrombotic properties, but their role outside the vascular bed is unknown. Granulosa cells form an avascular compartment in the ovarian follicle, in which a heparin-like activity has been described. At ovulation extravascular coagulation occurs around ovulatory follicles, and after expulsion of the oocyte, a fibrin clot forms in the antral cavity. Granulosa cells synthesize two major heparan sulfate proteoglycans, whose anticoagulant nature has not been investigated. The purpose of this study was to characterize anticoagulant heparan sulfate proteoglycans synthesized by rat ovarian granulosa cells. Affinity purified 35S-labeled anticoagulant heparan sulfate glycosaminoglycans represent 6.5% of the total heparan sulfate synthesized, and they contain 13% 3-O-sulfated disaccharides that are markers of the antithrombin-binding site of heparin. The biological activity of granulosa cell heparan sulfate proteoglycans was demonstrated by their ability to bind antithrombin and to accelerate the formation of thrombin-antithrombin complexes. The impact of hormonal stimulation on granulosa cell anticoagulant heparan sulfate proteoglycans was studied using 125I-antithrombin binding assays. Follicle-stimulating hormone induced a redistribution of anticoagulant heparan sulfate proteoglycans from the granulosa cell layer to the culture medium, indicating that their distribution could be modulated according to the stage of follicular development. These results suggest that anticoagulant heparan sulfate might be critically located in the follicle to maintain fluidity around the oocyte until its expulsion at ovulation.

Proteoglycans and hyaluronan in female reproductive organs

Proteoglycans and hyaluronan have been isolated from various female reproductive organs and fetal membranes. Special attention has been directed to changes in the composition of these molecules in the tissue during pregnancy and ovulation. Various chondroitin sulfate/dermatan sulfate proteoglycans, which represent extracellular matrix proteoglycans, are closely related to the organization of connective tissues. Heparan sulfate proteoglycans are widely distributed on the plasma membrane of most mammalian cells including those in the female reproductive organs. They are involved in various aspects of cell-to-cell or cell-to-extracellular matrix interactions. Although the precise biological functions of these proteoglycans are not currently clear, recent advances in biochemistry and molecular biology techniques promise an exciting new development in this area.

Effect of monensin on the sulfation of heparan sulfate proteoglycan from endothelial cells

Monensin is a monovalent metal ionophore that affects the intracellular translocation of secretory proteins at the level of trans-Golgi cisternae. Exposure of endothelial cells to monensin results in the synthesis of heparan sulfate and chondroitin sulfate with a lower degree of sulfation. The inhibition is dose dependent and affects the ratio [35S]-sulfate/[3H]-hexosamine of heparan sulfate from both cells and medium, with no changes in their molecular weight. By the use of several degradative enzymes (heparitinases, glycuronidase, and sulfatases) the fine structure of the heparan sulfate synthesized by control and monensin-treated cells was investigated. The results have shown that among the six heparan sulfate disaccharides there is a specific decrease of the ones bearing a sulfate ester at the 6-position of the glucosamine moiety. All other biosynthetic steps were not affected by monensin. The results are indicative that monensin affects the hexosamine C-6 sulfation, and that this sterification is the last step of the heparan sulfate biosynthesis and should occur at the trans-Golgi compartment.

Differential transport kinetics of chondroitin sulfate and dermatan sulfate proteoglycan by monkey aorta smooth muscle cells

Pulse-chase studies were performed to study the kinetics of chondroitin sulfate proteoglycan (CSPG) and dermatan sulfate proteoglycan (DSPG) transport in monkey aorta smooth muscle cells. During a short pulse (5 min) with [35S]Na2SO4 (500 microCi/ml), the cells synthesized 59% DSPG, 38% CSPG, and 3% heparan sulfate proteoglycan. Both DSPG and CSPG were transported out of the cell very rapidly after sulfate incorporation. At various chase times, proteoglycans (PGs) were isolated from four cellular compartments: (a) medium, (b) total cell lysate, (c) intracellular pool, and (d) extracellular pool. The PGs from the different pools were analyzed by Sepharose CL-2B column chromatography. The data of intracellular DSPG loss fitted a double exponential decay model: approximately 90% was secreted quickly with a t1/2 of 7 min, and the remaining 10% had a dramatically slower rate of secretion (t1/2 of 130 min). DSPG was rapidly secreted into the medium without prior accumulation in the extracellular matrix. In contrast, the loss of intracellular CSPG fitted a single exponential decay model with a t1/2 of 8 min; however, there was a significant accumulation of CSPG in the extracellular matrix compartment before release into the medium, resulting in a relatively slower secretion of CSPG into the medium (t1/2 of about 31 min). This delay in CSPG secretion into the medium is probably due to aggregation in the extracellular matrix, since addition of short hyaluronan oligomers (8-14 oligosaccharides) to the medium during the chase increased the rate of CSPG being secreted into the medium. We concluded that in aortic smooth muscle cell cultures, CSPG and DSPG are secreted via two distinct pathways through the cellular compartments.

The effects of monensin on blood-borne arrest and glycosylation of BL/VL3 lymphoma cells

We have previously shown that inhibitors of N-glycan processing alter both the cell surface carbohydrates and the homing properties in lymphoid cells. We have now studied the effects of the ionophore monensin (MON) on these parameters. Arrest in the spleen of [111In]-labelled BL/VL3 murine T lymphoma cells, injected intravenously was clearly reduced if the cells had been cultured for 24 h in the presence of monensin (0.1-1.0 microgram ml-1). We have characterized glycopeptides from BL/VL3 murine T lymphoma cells. Following labelling with tritiated precursors (fucose, mannose, galactose, glucosamine), surface glycopeptides from BL/VL3 murine T lymphoma cells, were released by trypsin and separated by gel filtration on Bio-Gel P6 and by affinity chromatography on immobilized lectins. After treatment with MON, a class of high molecular mass glycopeptides was no longer found. There were less complex and more high mannose glycans, as a consequence of a reduction of terminal glycosylation (sialylation, fucosylation or incorporation of N-acetyl-glucosamine). Similar findings were obtained with immunoprecipitated Thy-1 antigen. However, as estimated by flow cytometry analysis, the cell surface expression of Thy-1 was not reduced in MON-treated cells. Taken together our results show that cell surface oligosaccharides are modified dramatically, but that at least, certain cell surface antigens are present in normal amounts. It is tempting to speculate that changes in glycosylation account for the abnormal homing properties of MON-treated cells.

Alteration of intracellular traffic by monensin; mechanism, specificity and relationship to toxicity

Monensin, a monovalent ion-selective ionophore, facilitates the transmembrane exchange of principally sodium ions for protons. The outer surface of the ionophore-ion complex is composed largely of nonpolar hydrocarbon, which imparts a high solubility to the complexes in nonpolar solvents. In biological systems, these complexes are freely soluble in the lipid components of membranes and, presumably, diffuse or shuttle through the membranes from one aqueous membrane interface to the other. The net effect for monensin is a trans-membrane exchange of sodium ions for protons. However, the interaction of an ionophore with biological membranes, and its ionophoric expression, is highly dependent on the biochemical configuration of the membrane itself. One apparent consequence of this exchange is the neutralization of acidic intracellular compartments such as the trans Golgi apparatus cisternae and associated elements, lysosomes, and certain endosomes. This is accompanied by a disruption of trans Golgi apparatus cisternae and of lysosome and acidic endosome function. At the same time, Golgi apparatus cisternae appear to swell, presumably due to osmotic uptake of water resulting from the inward movement of ions. Monensin effects on Golgi apparatus are observed in cells from a wide range of plant and animal species. The action of monensin is most often exerted on the trans half of the stacked cisternae, often near the point of exit of secretory vesicles at the trans face of the stacked cisternae, or, especially at low monensin concentrations or short exposure times, near the middle of the stacked cisternae. The effects of monensin are quite rapid in both animal and plant cells; i.e., changes in Golgi apparatus may be observed after only 2-5 min of exposure. It is implicit in these observations that the uptake of osmotically active cations is accompanied by a concomitant efflux of H+ and that a net influx of protons would be required to sustain the ionic exchange long enough to account for the swelling of cisternae observed in electron micrographs. In the Golgi apparatus, late processing events such as terminal glycosylation and proteolytic cleavages are most susceptible to inhibition by monensin. Yet, many incompletely processed molecules may still be secreted via yet poorly understood mechanisms that appear to bypass the Golgi apparatus. In endocytosis, monensin does not prevent internalization. However, intracellular degradation of internalized ligands may be prevented.(ABSTRACT TRUNCATED AT 400 WORDS)

Intracellular acidosis protects cultured hepatocytes from the toxic consequences of a loss of mitochondrial energization

Cultured rat hepatocytes were treated with potassium cyanide, an inhibitor of cytochrome oxidase; valinomycin, a K+ ionophore; carbonyl cyanide m-chlorophenylhydrazone (CCCP), a protonophore; and the ATP synthetase inhibitor oligomycin. The effect of these agents on the viability of the cells was related to changes in ATP content and the deenergization of the mitochondria. The ATP content was reduced by over 90% by each inhibitor. All of the agents except oligomycin killed the cells within 4 h. With the exception of oligomycin, the mitochondrial membrane potential as measured by the distribution of [3H]triphenylmethylphosphonium collapsed with each of the agents. Monensin, a H+/Na+ ionophore, potentiated the toxicity of cyanide and CCCP, whereas the toxicity of valinomycin was reduced. The effect of cyanide and monesin on the cytoplasmic pH of cultured hepatocytes was measured with the fluorescent probe, 2',7'-biscarboxyethyl-5,6-carboxyfluorescein. Cyanide promptly acidified the cytosol, and the addition of 10 microM monensin caused a rapid alkalinization of the cytosol. A reduction of pH of the culture medium from 7.4 to 6.6 and 6.0 prevented the cell killing both by cyanide alone and by cyanide in the presence of monensin. However, neither monensin nor extracellular acidosis had any effect on the loss of mitochondrial energization in the presence of cyanide. It is concluded that ATP depletion per se is insufficient to explain the cell killing with cyanide, CCCP, and valinomycin. Rather, cell killing is better correlated with a loss of mitochondrial energization. With cyanide an intracellular acidosis interferes with the mechanism that couples collapse of the mitochondrial membrane potential to lethal cell injury.

Mitochondrial damage as a mechanism of cell injury in the killing of cultured hepatocytes by tert-butyl hydroperoxide

The killing of cultured hepatocytes by tert-butyl hydroperoxide (TBHP) occurs by different mechanisms depending on the presence or absence of the antioxidant N,N'-diphenylphenylenediamine (DPPD). In either situation there is evidence of mitochondrial damage. The mitochondrial inner membrane potential is lost, a result determined by the release from the cells of the lipophilic cation [3H]triphenylmethylphosphonium (TPMP+). Deenergization of the mitochondria is accompanied by a loss of ATP. Oligomycin reduced ATP stores without release of TPMP+ or without effect on the viability of the hepatocytes over the same time course that TBHP killed the majority of the cells. Monensin, a H+/Na+ ionophore, potentiated the toxicity of tert-butyl hydroperoxide in the presence or absence of DPPD. By contrast, extracellular acidosis reduced the toxicity of tert-butyl hydroperoxide in the presence or absence of DPPD. Neither monensin nor extracellular acidosis affected the metabolism of tert-butyl hydroperoxide, the release of TPMP+, or the extent of the peroxidation of cellular lipids. These data document the presence of mitochondrial damage in hepatocytes intoxicated with TBHP in both the presence and absence of DPPD. Furthermore, the potentiation by monensin is readily explained by the proposal that mitochondrial deenergization is accompanied by an intracellular acidosis. Such acidosis tends to delay the development of lethal cell injury. The protective effect of extracellular acidosis supports this interpretation.

Fibronectin and glycosaminoglycan synthesis by fibrotic pig fibroblasts in primary culture

Synthesis of fibronectin and glycosamingoglycans (GAGs) was studied in fibroblasts from pigs with post-irradiation subcutaneous fibrosis. Fibrosis was developed in the femoral muscle by local gamma irradiation with a dose of 60 Gy. Normal fibroblasts were obtained from the healthy skin of the same animal. To measure GAG and fibronectin synthesis fibrotic and normal fibroblasts were labeled with 3H-glucosamine, 35S-sulfate and 35S-methionine. Fibrotic fibroblasts synthesized 2.5 times as much fibronectin as normal skin fibroblasts but total protein synthesis did not change. Parallel enhanced secretion of hyaluronic acid and dermatan sulfate into the cell culture medium were also observed. GAGs from the pericellular layer of trypsin-digested fibrotic fibroblasts exhibited increased 3H incorporation, but reduced 35S-sulfate incorporation. The largest reduction in the latter was observed for heparan sulfate. These results indicate that the fibroblasts from the well developed fibrotic tissue maintain enhanced synthesis of matrix macromolecules in primary cultures. Structural and/or metabolic changes in secreted GAGs, combined with the stimulation of tissue repair by growth factors may be responsible for the excessive deposition of collagen in post-irradiation fibrosis.

Cell biology of arterial proteoglycans

Although proteoglycans constitute a minor component of vascular tissue, these molecules have been shown to influence a number of arterial properties such as viscoelasticity, permeability, lipid metabolism, hemostasis, and thrombosis. A hallmark of early and late atherosclerosis is the accumulation of proteoglycans in the intimal lesions. Yet, it is not clear why this accumulation occurs. This article reviews the classes of proteoglycans synthesized by the two major cell types of the arterial wall--the endothelial and smooth muscle cell. Detailed consideration is then given to the modulation of proteoglycan metabolism and the role that proteoglycans play in a number of cellular events such as adhesion, migration, and proliferation--important processes in both the development and the pathogenesis of blood vessels. Last, the involvement of proteoglycans in two critical vascular wall processes--hemostasis and lipid metabolism--is reviewed, because these events pertain to atherogenesis. This review emphasizes the importance of proteoglycans in regulating several key events in normal and pathophysiological processes in the vascular tissue.

Cell surface heparan sulfate proteoglycan and the neoplastic phenotype

Cell surface proteoglycans are strategically positioned to regulate interactions between cells and their surrounding environment. Such interactions play key roles in several biological processes, such as cell recognition, adhesion, migration, and growth. These biological functions are in turn necessary for the maintenance of differentiated phenotype and for normal and neoplastic development. There is ample evidence that a special type of proteoglycan bearing heparan sulfate side chains is localized at the cell surface in a variety of epithelial and mesenchymal cells. This molecule exhibits selective patterns of reactivity with various constituents of the extracellular matrix and plasma membrane, and can act as growth modulator or as a receptor. Certainly, during cell division, membrane constituents undergo profound rearrangement, and proteoglycans may be intimately involved in such processes. The present work will focus on recent advances in our understanding of these complex macromolecules and will attempt to elucidate the biosynthesis, the structural diversity, the modes of cell surface association, and the turnover of heparan sulfate proteoglycans in various cell systems. It will then review the multiple proposed roles of this molecule, with particular emphasis on the binding properties and the interactions with various intracellular and extracellular elements. Finally, it will focus on the alterations associated with the neoplastic phenotype and will discuss the possible consequences that heparan sulfate may have on the growth of normal and transformed cells.

Effect of thyroid hormone deficiency on proteoglycan synthesis by human skin fibroblast cultures

Proteoglycans and hyaluronic acid synthesized by human skin fibroblasts in culture were characterized, and the effect of thyroid hormone deficiency was examined. The fibroblasts in culture synthesize hyaluronic acid, dermatan sulfate (DS) proteoglycans and heparan sulfate (HS) proteoglycans. Hyaluronic acid is almost exclusively secreted into the medium. Among the proteoglycans synthesized during 24 h label, about 70% were secreted into the medium and the remaining 30% were associated with the cell layer. About 70% of proteoglycans secreted into the medium contained DS and the remaining 30% contained HS. For cell-associated proteoglycans, 60% contained HS and the remainder contained DS. The size distributions of the glycosaminoglycans from both DS and HS proteoglycans were similar, with an average Mr of approximately 30,000. Incubation of fibroblasts in thyroid hormone deficient medium increased net synthesis of hyaluronic acid (approximately 50%) and all species of proteoglycans (approximately 85%). 3H/35S ratios in the chondroitin 4-sulfate disaccharide isolated with HPLC were not altered in thyroid hormone deficient cultures, indicating that the specific activity of 3H in UDP-N-acetylhexosamine precursors did not change. The increased incorporation of 3H into hyaluronic acid and of 3H and 35S into DS and HS proteoglycans thus indicates increased net synthesis. Degradation of cell-associated proteoglycans was not influenced by thyroid hormone deficiency.

The effect of monensin on thyroglobulin secretion. Studies with isolated follicles from pig thyroids

The effect of monensin on the secretion of thyroglobulin was studied in open follicles isolated from pig thyroid tissue; in this system, thyroglobulin is secreted into the incubation medium. When monensin was present during a 4-h chase incubation after pulse-labelling with 3H-leucine, the secretion of labelled thyroglobulin was reduced by about 85%; in electron-microscopic autoradiographs of rat thyroid lobes labelled and chase-incubated under similar conditions the relative number of grains over follicle lumina was strongly reduced when monensin was present during the chase. These observations are in agreement with the consensus that monensin arrests transport of secretory proteins in the Golgi complex. In other experiments, pulse-labelled follicles were chase-incubated for 1.5 h whereby labelled thyroglobulin was transported from the RER to exocytic vesicles. Monensin present during a subsequent chase of 0.5 h caused only a moderate decrease of labelled thyroglobulin secretion. TSH present during the second chase-stimulated secretion in both control and monensin-exposed follicles. TSH also caused a drastic reduction of exocytic vesicles in rat thyroid lobes, and the number of vesicles remaining in the cells was the same in controls and lobes exposed to the ionophore. The observations are interpreted to show that monensin does not inhibit the basal or TSH-stimulated transport of thyroglobulin from the site of monensin-induced arrest in the Golgi complex to the apical cell surface or the exocytosis of thyroglobulin.

Sodium ion influx in proliferating lymphocytes: an early component of the mitogenic signal

Stimulation of pig peripheral blood lymphocytes with concanavalin A (Con A) provoked a rapid increase (two- to threefold) in the rate of ouabain-inhibitable K+ uptake observable within 3-10 min of stimulation with mitogen. At least two phases can be distinguished in the activation of the Na+/K+ pump: the early phase (till 3 h) is characterized by an unaltered number of ouabain binding sites and the later phase (noted at 5 h) by an increased number of such sites. Both K+ efflux and influx increased to the same extent, thereby maintaining [K+]i at the same level as in resting cells (120 mM). Within 3 min of addition of mitogen, the rates of total and amiloride-inhibitable Na+ uptake went up two- and fourfold, respectively, thus resulting in rapid increase in [Na+]i from 20 to about 50 mM. Activation of the Na+/K+ pump was not observed when the cells were stimulated with Con A in low Na+ medium (9 mM), nor did the usual rise in [Na+]i occur. When monensin (30 microM), a Na+/H+ ionophore, was added to resting cells, an increase in both [Na+]i and active K+ uptake occurred in normal medium but not when cells were suspended in low Na+ isotonic buffer. Amiloride (500 microM), on the other hand, prevented both the Con A-induced increase in [Na+]i and the activation of the Na+/K+ pump. Despite complete inhibition of the Na+,K+-ATPase in the presence of ouabain (1 mM), Con A activated the amiloride-inhibitable Na+ uptake in the usual way. In mouse splenocytes stimulated with Con A, there was also a parallel rise in both [Na+]i and active K+ uptake but this took considerably longer to occur than was the case in pig peripheral blood lymphocytes. Increase in both ionic fluxes, the former passive and the latter active, is essential to the entry and maintenance of the cells in proliferative cycle.

High-performance ion-exchange chromatographic separation of proteoglycans

Proteoglycans synthesized by cultured human muscle cells were separated by ion-exchange high-performance liquid chromatography using a Bio-gel TSK DEAE 5-PW analytical column. The procedure requires only 40 min to complete. The same analytical size column can be used for either analytical or semipreparative scale separations without significant loss of resolution. Proteoglycans elute from the TSK column with a similar recovery and at similar elution ionic strengths when compared to the established cellulose-based chromatographic gel, DEAE-Sephacel. The technique has been applied to the analysis of chondroitinase-digested samples and is particularly useful for rapid screening of large numbers of cultures for both biosynthetic rate studies and analysis of patterns of proteoglycan synthesis.

Tunicamycin inhibits proteoglycan synthesis in rat ovarian granulosa cells in culture

The effects of tunicamycin, an inhibitor of N-linked oligosaccharide biosynthesis, on the synthesis and turnover of proteoglycans were investigated in rat ovarian granulosa cell cultures. The synthesis of proteoglycans was inhibited (40% of the control at 1.6 micrograms/ml tunicamycin) disproportionately to that of general protein synthesis measured by [3H]serine incorporation (80% of control). Proteoglycans synthesized in the presence of tunicamycin lacked N-linked oligosaccharides but contained apparently normal O-linked oligosaccharides. The dermatan sulfate and heparan sulfate chains of the proteoglycans had the same hydrodynamic size as control when analyzed by Sepharose 6B chromatography. However, the disulfated disaccharide content of the dermatan sulfate chains was reduced by tunicamycin in a dose-dependent manner, implying that the N-linked oligosaccharides may be involved in the function of a sulfotransferase which is responsible for sulfation of the iduronic acid residues. When [35S]sulfate and [3H]glucosamine were used as labeling precursors, the ratio of 35S/3H in chondroitin 4-sulfate was reduced to approximately 50% of the control by tunicamycin, indicating that the drug reduced the supply of endogenous sugar to the UDP-N-acetylhexosamine pool. Neither transport of proteoglycans from Golgi to the cell surface nor their turnover from the cell surface (release into the medium, or internalization and subsequent intracellular degradation) was affected by the drug. Addition of mannose 6-phosphate to the culture medium did not alter the proteoglycan turnover. When granulosa cells were treated with cycloheximide, completion of proteoglycan diminished with a t1/2 of approximately 12 min, indicating the time required for depleting the core protein precursor pool. The glycosaminoglycan synthesizing capacity measured by the addition of p-nitrophenyl-beta-xyloside, however, lasted longer (t1/2 of approximately 40 min). Tunicamycin decreased the core protein precursor pool size in parallel to decreased proteoglycan synthesis, both of which were significantly greater than the inhibition of general protein synthesis. This suggests two possibilities: tunicamycin specifically inhibited the synthesis of proteoglycan core protein, or more likely a proportion of the synthesized core protein precursor (approximately 50%) did not become accessible for post-translational modifications, and was possibly routed for premature degradation.

Decreased synthesis and increased intracellular degradation of newly synthesized collagen in freshly isolated chick tendon cells incubated with monensin

The synthesis and secretion of procollagen in embryonic chick tendon fibroblasts in suspension culture were inhibited with the carboxylic ionophore monensin. The synthesis of procollagen was inhibited by 50% in a 2-h exposure to 0.1 microM monensin and was inhibited by 70% in a 6-h exposure to 0.1 microM monensin. Secretion of procollagen was inhibited by greater than 90% in the 0.1 microM monensin-treated cultures and was totally inhibited by higher doses of the reagent. A cellular pool of collagenase-digestible peptides was demonstrated in the control cells, the level of which was elevated 3-4 times in the monensin-treated cultures. In order to determine whether the secretory and synthesis block caused by monensin inhibited intracellular degradation of newly synthesized collagen, the hydroxy[14C]proline in degraded collagen fragments present in control and monensin-treated cultures was determined and compared to the total hydroxy[14C]proline synthesized in each culture. The intracellular degradation of newly synthesized, pulse-labeled collagen was shown to proceed at rates comparable to those seen in the control cultures. The monensin-treated cells degraded pulse-labeled newly synthesized collagen nearly twice as long as the controls, resulting in an overall increase in the fraction of newly synthesized collagen that was degraded. These findings suggest that force generation in the activated cross-bridge cycle may occur as a result of an actin-attached cross-bridge transition between these two orientations.

Synthesis of hyaluronic acid is decreased and synthesis of proteoglycans is increased when cultured mouse epidermal cells differentiate

Newborn mouse epidermal cells proliferate when cultured in 0.05 mM Ca++ medium and terminally differentiate when the Ca++ is increased to about 1.2 mM, the level found in most cell culture media. We found that hyaluronic acid and proteoglycans were synthesized by isolated cultured newborn mouse epidermal cells and that quantitative and qualitative changes in these macromolecules appeared when proliferating epidermal cultures were induced to differentiate by calcium. A major change that occurred with differentiation was a reduction in synthesis of hyaluronic acid while synthesis of proteoglycans and glycoproteins increased. The proteoglycans synthesized in these cultures were heparan sulfate-proteoglycan (90%) and chondroitin sulfate-proteoglycan (10%), regardless of the calcium level.

The effect of mannose 6-phosphate on the turnover of the proteoglycans in the extracellular matrix of human fibroblasts

Human fibroblasts (SL66) were cultured in medium containing 35SO2-4 to label the glycosaminoglycans (GAGs). The cells were then detached from the culture dish to leave radioactively-labeled components of the extracellular matrix, hereafter termed 35S-labeled substrate-attached material. When unlabeled SL66 fibroblasts were plated onto this 35S-labeled substrate-attached material, the cells mediated two distinct events: (a) release of radioactivity from the substrate-attached material into the medium; (b) degradation of certain glycosaminoglycans into radioactive components of very low molecular weight including free radioactive sulfate. In the presence of mannose 6-phosphate, however, the degradation of the substrate-attached material by SL66 cells was partially inhibited. Analyses of this effect in terms of the dose-response curve, saccharide specificity, ammonium chloride sensitivity, and the requirement for cells suggest that both an intracellular compartment and the mannose 6-phosphate receptor that binds lysosomal enzymes at the cell surface may play important roles in the turnover and degradation of certain proteoglycans in substrate-attached material.

Expression of tracheal differentiated functions in serum-free hormone-supplemented medium

Most dissociated airway epithelial cells in culture express few of their in vivo functions and only to a limited degree. In this report, we demonstrate that hamster tracheal epithelial (HTE) cells cultured on a collagen gel substratum in a serum-free hormone-supplemented medium differentiate to cilia-beating and mucus-secreting cell types. The medium is Ham's F-12 supplemented with insulin, epidermal growth factor, transferrin, hydrocortisone, cholera toxin, bovine hypothalamus extract, and vitamin A. Under these culture conditions, HTE cells exhibit a growth rate of 24 h/population doubling and reach confluency, at a density of 2-5 X 10(4) cells/cm2, within 2 weeks. Both the collagen gel substratum and vitamin A of this culture system are important to the growth and differentiation of HTE cells in vitro. Evidence of HTE cell differentiation has been obtained at both the ultrastructural and the histochemical levels. In addition, a variety of biochemical studies (gel filtration, ion exchange column chromatography, enzyme digestion, nitrous acid treatment, and composition analysis) indicate the production of mucin-like glycoprotein in the HTE cultures. The levels of mucin-like glycoprotein were found to closely correlate with the histochemically quantitated levels of the mucous cell type. Kinetic studies demonstrate that HTE cells rapidly lose their differentiated features during the attachment stage of primary culture but redifferentiation occurs after the cultures reach confluency. The ability of HTE cells to grow and differentiate in this serum-free culture system in the absence of other cell types should greatly facilitate the study of mucociliary functions in vitro.