Tyrosine sulfation is not the last modification of entactin before its secretion from 3T3-L1 adipocytes

Tyrosine sulfation of entactin was studied by labeling of 3T3-L1 adipocytes with [35S]methionine or H2 35SO4 in the presence or absence of tunicamycin or monensin. Four precursors (EN1-4) at different steps of modification were detected in addition to mature entactin. Under normal conditions, EN2 and mature entactin were intracellular species, and the latter was sulfated and secreted. Inhibition of co-translational transfer of N-linked oligosaccharides by tunicamycin produced EN1 and EN3 as intracellular species, and EN3 was sulfated and secreted. Interruption of protein transport from medial to trans (distal) Golgi cisternae by monensin, and consequent blockage of terminal glycosylation caused intracellular accumulation of EN4. EN4 was sulfated and of different size compared to mature entactin. These facts suggested that tyrosine sulfation of entactin occurs in medial Golgi cisternae and is not the last modification before its secretion. Our results appeared inconsistent with recent observations by Baeuerle and Huttner [(1987) J. Cell Biol. 105, 2655-2664] that tyrosine sulfation of IgM occurred within the trans (distal) Golgi cisternae as the last modification before its exit from the Golgi complex.     

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

Rat ovarian granulosa cells, isolated from immature female rats 48 h after stimulation with 5 IU of pregnant mare's serum gonadotropin, were maintained in culture. The effects of monensin, a monovalent cationic ionophore, on various aspects of proteoglycan metabolism were studied by metabolically labeling cultures with [35S]sulfate, [3H]glucosamine, or [3H]glucose. Monensin inhibited post-translational modification of both heparan sulfate (HS) proteoglycans and dermatan sulfate (DS) proteoglycans, resulting in decreased synthesis of completed proteoglycans [( 35S]sulfate incorporation decreased to 10% of control by 30 microM monensin, with an ED50 approximately 1 microM). Proteoglycans synthesized in the presence of monensin showed undersulfation of both DS and HS glycosaminoglycans and altered N-linked and O-linked oligosaccharides, suggesting that the processing of all sugar moieties is closely associated. Monensin caused a decrease in the endogenous sugar supply to the UDP-N-acetylhexosamine pool as indicated by an increased 3H incorporation into DS chains [( 3H]glucosamine as precursor) in spite of the decrease in glycosaminoglycan synthesis. Monensin reduced and delayed transport of both secretory and membrane-associated proteoglycans from the Golgi complex to the cell surface. It took 2-4 min for newly labeled proteoglycans to reach the main transport process inhibited by monensin. Monensin at 30 microM did not prevent internalization of cell surface 35S-labeled proteoglycans but almost completely inhibited their intracellular degradation to free [35S]sulfate (ED50 approximately 1 microM), resulting in intracellular accumulation of both DS and HS proteoglycans. Pulse-chase experiments demonstrated that one of the intracellular degradation pathways involving proteolysis of both DS and HS proteoglycans and limited endoglycosidic cleavage of HS continued to operate in the presence of monensin. These results suggest that the intracellular degradation of proteoglycans involve both acidic and nonacidic compartments with monensin inhibiting those processes that normally occur in such acidic compartments as endosomes or lysosomes by raising their pH.     

Secretion of chondroitin SO4 by monolayer cultures of chick embryo chondrocytes

Monolayer cultures of chick embryo tibial chondrocytes incorporate 35SO42- into chondroitin SO4 which is rapidly secreted from the cells into two extracellular pools. Part of the extracellular chondroitin SO4 is recovered in a soluble form in the culture medium, and the remainder is associated with the cell matrix from which it is released by isotonic trypsinization. At 38 degrees C labeled chondroitin SO4 appears in the cell matrix fraction within 5 min after addition of 35SO42- and in the culture medium fraction 15 min after 35SO42- is added. The intracellular pool of labeled chondroitin SO4 reaches a steady state level of 150 to 200 pmol of bound SO4 per 10(6) cells in 60 min, while the cell matrix and medium fractions increase at rates of 3 and 1 nmol of bound SO4 per h per 10(6) cells, respectively. After 4 h of labeling, less than 20% of the newly synthesized cell-associated chondroitin SO4 is in the intracellular fraction. By labeling cells for 15 min at 25 degrees C 80% of the cell-associated chondroitin 35SO4 is obtained in the intracellular fraction. This material is chased without lag into both the cell matrix fraction and the medium fraction. A mixture of NaF and NaCN, both at 30 mM, lowers the cellular ATP level to 15% of normal and blocks secretion of the intracellular chondroitin SO4 into both extracellular fractions. Colchicine at 10(-6) M gives a partial inhibition of both synthesis and secretion of chondroitinSO4. Sucrose density gradient sedimentation analysis of the intracellular chondroitin SO4 and the two extracellular fractions shows that all three fractions contain both a heavy and light proteoglycan fraction. The intracellular light proteoglycan fraction is secreted preferentially into the culture medium where it represents 30% of the total culture medium pool. The ratio of 6-sulfated GalNAc to 4-sulfated GalNAc in the heavy proteochondroitin SO4 fraction is approximately twice that found for the light fraction.     

Metabolic effects of forskolin in chick chondrocytes

The effects of forskolin on parameters of energy metabolism and proteoglycan synthesis have been investigated in chick embryo sternal chondrocyte cultures. After 8 h exposure to 100 microM forskolin, ATP levels and oxygen consumption were unaltered. Protein synthesis was unaffected up to 50 microM forskolin and protein degradation was unaffected by forskolin up to 100 microM. In contrast, incorporation of the proteoglycan precursors, 35SO4 and [3H]glucosamine, was more sensitive to forskolin. Inhibition was linear with dose between 10 and 100 microM, reaching 70% at 100 microM. Incorporation of 35SO4 into glycosaminoglycan chains initiated on an artificial beta-xyloside acceptor was inhibited in the same manner. cAMP accumulation was maximal at 10 microM forskolin, a concentration which did not alter proteoglycan synthesis. We conclude that a major, acute effect of forskolin in these short-term experiments is inhibition of proteoglycan synthesis in a cAMP-independent manner.     

Differential effects of leupeptin, monensin and colchicine on ligand degradation mediated by the two asialoglycoprotein receptor pathways in isolated rat hepatocytes.

We have shown that degradation of asialo-orosomucoid (ASOR) in isolated rat hepatocytes occurs by two different intracellular pathways [Clarke, Oka & Weigel (1987) J. Biol. Chem. 262, 17384-17392] mediated by two subpopulations of cell surface galactosyl (Gal) receptors, designated State 1 or State 2 receptors. In the present study, several inhibitors were tested for their effects on ligand degradation by the State 1 or State 2 pathway. Leupeptin, monensin and chloroquine completely inhibited degradation of 125I-labelled ASOR in both pathways. Dose-response studies showed, however, that the State 2 pathway was more sensitive to leupeptin or monensin than the State 1 pathway. No differences were observed with chloroquine. For example, the onset of inhibition in the State 2 and State 1 pathways occurred at about 0.05 and 0.3 microM-leupeptin respectively, a 6-fold difference. At 3.5 microM-monensin, 125I-ASOR degradation in the State 2 pathway was completely blocked, whereas degradation in the State 1 pathway was essentially unaffected. Colchicine was observed to give the largest differential sensitivity between the two pathways. The State 2 degradation pathway was about 30-fold more sensitive to colchicine than the State 1 pathway. Lumicolchicine had no affect. The onset of inhibition of the rate of 125I-ASOR degradation in the State 2 and State 1 pathways occurred at approximately 0.1 and 3.0 microM-colchicine respectively. At very high concentrations (greater than 0.1 mM), the State 1 pathway could be completely inhibited. We conclude that intracellular 125I-ASOR processing or delivery to degradative compartments in both the State 1 and State 2 Gal receptor pathways requires low pH. Ligand delivery to the degradative compartment does not require microtubules in the State 1 pathway, consistent with the very rapid onset of degradation in this pathway. The State 2 degradation pathway does require microtubules.     

Effects of Monensin and Colchicine on Myelin Galactolipids

Monensin and colchicine have been used in a variety of systems to disrupt functioning of the Golgi apparatus and transport of Golgi-derived vesicles to the plasma membrane. In this study the effects of monensin and colchicine on the synthesis of cerebroside and sulfatide and their appearance in myelin were examined to determine whether these myelin components are processed through the Golgi apparatus. Brain slices from rats 17 days old were incubated with [3H]galactose and [35S]-sulfate to label cerebroside and sulfatide. Myelin was isolated on sucrose density gradients. Fractions highly enriched in cerebroside and sulfatide were prepared from homogenates and myelin fractions by lipid extraction, alkaline methanolysis, and in some cases TLC. Monensin at 0.1 microM had no significant effect on synthesis of these galactolipids as measured by incorporation of [3H]-galactose into cerebroside or [35S]sulfate into sulfatide in homogenates. However, appearance of [35S]sulfatide in the myelin fraction was reduced to 49% of control, while appearance of [3H]cerebroside was not significantly reduced. Colchicine from 1 mM to 0.1 microM had effects similar to monensin, that is, appearance of [35S]sulfatide in myelin was depressed, but again [3H]cerebroside was not affected. Incorporation of [35S]sulfate into sulfatide in homogenate was 93% of control, while appearance of [35S]sulfatide in the myelin fraction was depressed to 58% of control. The inhibition of appearance of sulfatide in myelin by colchicine and monensin is consistent with the view that sulfation of cerebroside occurs in the Golgi and that sulfatide is transported via Golgi-derived vesicles to the forming myelin membrane.(ABSTRACT TRUNCATED AT 250 WORDS)     

Secretion of lysyl oxidase by cultured human skin fibroblasts and effects of monensin, nigericin, tunicamycin and colchicine

Lysyl oxidase is an extracellular enzyme that initiates crosslink formation in the major connective tissue proteins, the collagens and elastin. This enzyme activity accumulated in a fresh medium of cultured human skin fibroblasts for at least 24 h, but the accumulation was distinctly non-linear after the first 12 h. Most of the total enzyme activity was present in the medium, the activity found in the cell layer representing about 30% of the total activity at 4 h, and about 10-15% at 24 h. The bulk of the cell-layer-associated activity appeared to be extracellular, as more than half was lost upon trypsinization. Culturing of the cells for 8 h in the presence of either monensin or nigericin, ionophores known to inhibit the secretion of many proteins at the level of the Golgi complex, markedly reduced the accumulation of lysyl oxidase activity in the medium. Monensin was particularly effective, as it produced a distinct inhibition even at a 10 nM concentration, reaching 50% at 30 nM. Both ionophores also reduced enzyme activity in the cell layer, whereas no definite decrease was seen in the activity of the trypsinized cells. The effect of monensin was evidently not due to any general toxicity on the part of the drug, since even a 500 nM concentration gave no inhibition of the incorporation of [3H]leucine into total protein. Tunicamycin also reduced lysyl oxidase activity in the medium and to a lesser extent in the cell layer, but the effective dose, 1-10 micrograms/ml, also inhibited the incorporation of [3H]leucine into total protein. The reduced enzyme activity may therefore not be due to a direct effect of tunicamycin on the glycosylation of the lysyl oxidase protein itself but may be mediated through other actions of the drug. Colchicine caused no inhibition in lysyl oxidase activity secretion even at a 10 microM concentration, although it has been reported to inhibit collagen secretion at doses more than one order of magnitude lower.     

Influence of cytochalasin d-induced changes in cell shape on proteoglycan synthesis by cultured articular chondrocytes

There is growing evidence that cell shape regulates both proliferation and differentiated gene expression in a variety of cell types. We have explored the relationship between the morphology of articular chondrocytes in culture and the amount and type of proteoglycan they synthesize, using cytochalasin D to induce reversible cell rounding. When chondrocytes were prevented from spreading or when spread cells were induced to round up, 35SO4 incorporation into proteoglycan was stimulated. Incorporation into the cell layer was stimulated more than into the medium. When the cells were allowed to respread by removing cytochalasin D, proteoglycan synthesis returned to control levels. Cytochalasin D-induced stimulation of 35SO4 incorporation reflected an increase in core protein synthesis rather than lengthening of glycosaminoglycan chains, because [3H]serine incorporation into core protein was also stimulated. The observed stimulation of proteoglycan synthesis was not due to an overall stimulation of protein synthesis, to inhibition of DNA synthesis, or to accumulation of cells in one phase of the cell cycle. Cytochalasin D-treatment of cells in suspension caused no further stimulation of 35SO4 incorporation, suggesting that the observed effects were due to cell rounding rather than exposure to cytochalasin D per se; nevertheless, we cannot completely rule out other, nonspecific, effects of the drug. Fibroblasts and chondrocytes that had been passaged to stimulate dedifferentiation did not incorporate more 35SO4 when treated with cytochalasin D, suggesting that increased proteoglycan synthesis in response to rounding may itself be a differentiated property of chondrocytes.     

Anti-inflammatory drugs, prostanoid and proteoglycan production by cultured bovine articular chondrocytes

The effect of various anti-inflammatory drugs on the production of prostaglandins E2 and F2 alpha, 6 keto PGF1 alpha and thromboxane B2 by bovine articular chondrocytes was measured by radioimmunoassay. While indomethacin and meclofenamic acid caused a dose-dependent inhibition of all prostanoids measured, the effects of hydrocortisone and colchicine varied with respect to different prostanoids. Hydrocortisone (10(-7)M - 10(-13)M) both in the presence and absence of added arachidonic acid, resulted in an inhibition of prostaglandins E2 and F2 alpha, and to a lesser extent, 6 keto PGF 1 alpha, but TxB2 production was only slightly inhibited by the drug in the absence of arachidonic acid and markedly increased in its presence. Colchicine (10(-7)M-10(-3)M) had the opposite effect, causing an inhibition of TxB2 and stimulating PGE2 and 6 keto PGF1 alpha production. These findings suggest that certain anti-inflammatory drugs may, in addition to their action on phospholipase A2 and cyclo-oxygenases, exert potent effects at the level of the different synthetases. In order to see whether these alterations in relative prostanoid levels affected proteoglycan metabolism, the effect of anti-inflammatory drugs on proteoglycan synthesis by cultured chondrocytes was tested using 35SO4 labeling methodology. The results showed that at the concentrations tested (10(-5)M to 10(-7)M), indomethacin, dexamethasone, hydrocortisone and colchicine inhibited 35SO4 incorporation into newly synthesized proteoglycan molecules both in the presence (10(-6)M) and absence of exogenous arachidonic acid. In the same concentration range chloroquine had no effect. These results do not support the hypothesis of direct prostanoid involvement in the modulation of proteoglycan synthesis in articular cartilage.     

The effect of colchicine and dibucaine on the morphogenesis of Semliki Forest virus

The effect of colchicine, Nocodazole, and dibucaine on the assembly of Semliki Forest virus was investigated. Colchicine, Nocodazole, and dibucaine reduced the production of extracellular virus by 75 to 90%. Lumicolchicine had no effect on virus growth. Other control experiments showed no effect by these drugs on the incorporation of [3H]leucine into material precipitated by trichloroacetic acid. Colchicine (100 micron) disrupted the microtubles of the baby hamster kidney cells (BHK-21), whereas dibucaine did not alter microtubule polymerization. The stage of virus assembly inhibited by colchicine and dibucaine was studied by experiments with [3H]-leucine or [35S]methionine. At various times after addition of one of these drugs, the incorporation of the labeled precursors into viral proteins associated with fractions enriched for endoplasmic reticulum or plasma membrane from the cell was evaluated. The results clearly show that the envelope and nucleocapsid proteins of the virus move to the plasma membrane of the cell where they accumulate. The studies strongly suggest that the cytoskeletal system is involved in the final stages of morphogenesis of Semliki Forest virus from the plasma membrane.     

The effect of avian retroviruses on limb bud chondrogenesis in vitro

Mesenchymal cells isolated from stage 24 embryonic chicken limb buds were infected with the temperature-sensitive transformation mutants of Rous sarcoma virus tsNY68, tsNY10 and tsLA25 at the nonpermissive temperature for transformation (41 degrees C). Virus infection greatly inhibited subsequent limb bud chondrogenesis under nontransforming conditions, as indicated by a reduction in the rate of 35SO4 incorporation into cell-associated proteoglycans. The inhibition of chondrogenesis was directly related to the percentage of cells infected with tsNY68 at 41 degrees C. The observed inhibition of chondrogenesis was independent of src gene expression since this effect was also caused by many viruses which lack the src gene, including the leukosis viruses RAV-1, RAV-2 and MAV-2(0); the src deletion mutant RSVtd107; and the reticuloendotheliosis viruses REV-T and SNV. Infection of mesenchymal cells with tsNY68 under nontransforming conditions did not cause changes in parameters such as the rate of thymidine incorporation, total cell DNA and total cell protein. Infection with tsNY68 at 41 degrees C resulted in altered kinetics of 35SO4 incorporation into cell-associated proteoglycans and a corresponding reduction in 35SO4-labeled proteoglycans extracted from the cell layer. There were no apparent quantitative effects on the rate of accumulation of proteoglycans in the culture medium. The proteoglycans extracted from the cells and the collected medium of tsNY68-infected cultures were smaller than those of uninfected cultures, as shown by agarose gel chromatography.     

The intracellular localisation of proteoglycans and their accumulation in chondrocytes treated with monensin

Pig laryngeal chondrocytes incubated in the presence of monensin showed inhibition of [³⁵S]sulphate incorporation and decreased secretion of proteoglycan into the culture medium, but no large decrease in protein synthesis. This lead to the intracellular accumulation of proteoglycan protein core, which was detected in immunoprecipitates of cell extracts. Using the same antiserum protein core was localised by electron microscopy with protein A-coated gold. In control chondrocytes, it was detected only in elements of the Golgi and in secretory vesicles, but following monensin treatment labelling was more intense in the Golgi and extended into the distended cisternae of the rough endoplasmic reticulum. The results suggest that monensin blocks proteoglycan protein core translocation between different elements of the Golgi and that this occurs prior to the major site of chondroitin sulphate synthesis on proteoglycan.     

Abnormal laminin secretion from parietal endoderm-like F9 cells in the presence of monensin

We studied the effects of monensin on post-translational modification and intracellular transport of precursors of laminin subunits in parietal endoderm-like F9 cells. At concentrations higher than 0.1 microM, monensin inhibited the processing of high-mannose type precursors for all three subunits and caused their cytoplasmic accumulation. Furthermore, the secretion of mature subunits of laminin was inhibited. Instead, polypeptides with similar molecular weights to those of intracellular precursors were secreted. These polypeptides were immunologically related to laminin subunits and were sensitive to digestion with beta-N-acetylglucosaminidase H (Endo H). This indicated that Golgi complexes of the cells can transport the precursors of laminin subunits even with their terminal glycosylation inactivated by monensin. Tunicamycin induced the accumulation of unglycosylated precursors and strongly reduced their secretion into the medium.     

Influence of colchicine on the synthesis and secretion of proteoglycans and collagen by fetal guinea pig chondrocytes

Fetal guinea-pig epiphyseal chondrocytes were cultured in monolayers and as aggregates in the presence of antimicrotubular agents. Colchicine and vinblastine caused a dissociation of the Golgi complex, in addition to the disappearance of microtubules. Synthesis and secretion of proteoglycans and collagen were studied using radioactive precursors. Colchicine inhibited the synthesis of proteoglycans. The drug also inhibited secretion with an intracellular accumulation of these molecules. The proteoglycans secreted by the colchicine-treated cells had a smaller molecular size and contained a smaller proportion of aggregated molecules than proteoglycans in control cultures. However, there was no difference in the average size of the chondroitin sulfate side chains of the proteoglycan molecules. Nor was there any increase in the breakdown of proteoglycans in colchicine-treated cultures. Vinblastine was also found to inhibit synthesis and secretion of proteoglycans. Deuterium oxide also inhibited the synthesis of these molecules but stimulated their secretion into the medium. Colchicine caused an inhibition of both synthesis and secretion of collagen. It is suggested that the quantitative and qualitative effects of colchicine could be the result of disturbances in the Golgi complex, possibly in combination with a retarded translocation of secretory vacuoles. However, as the colchicine-treated chondrocytes were still able to continue a large part of their matrix biosynthesis with only moderate changes in the structure of the secreted molecules, it is probable that alternative pathways for the secretion of matrix molecules exist and/or the Golgi complex is able to retain a major part of its function despite the structural alterations.     

Concanavalin A affects glycosaminoglycans cellular and extracellular accumulation in cultured embryonic fibroblasts

Incorporation of 3H glucosamine and 35SO4 into glycosaminoglycans and proteoglycans produced and secreted by 7, 11 and 14 day chick embryo fibroblasts in vitro after concanavalin A treatment has been determined. Lectin differently affects 3H and 35SO4 incorporation. It enhances 3H labelled GAG accumulation in both cellular and extracellular compartments. Total incorporation of 35SO4 remains unchanged whereas the intracellular one is stimulated and the extracellular is reduced. All the effects are more relevant in the early stages of development. HA and PG cellular and extracellular accumulation seems to be independently regulated.     

Stimulation of cartilage macromolecule synthesis by adenosine 3',5'-monophosphate.

The role of cyclic AMP in the regulation of cartilage macromolecule synthesis in vitro was studied in pelvic cartilage from 10-12 day chick embryos. Incubation of cartilages in medium containing 0.5 mM cyclic AMP resulted in a 30% inhibition of 35SO4-2, [3H]leucine and [3H]uridine incorporation into proteoglycan, total protein and RNA, respectively. Higher concentrations of cyclic AMP had no greater effects. In contrast, butyrylated cyclic AMP derivatives (0.5-5.0 mM) added to the incubation medium stimulated (50-100%) the incorporation of these radiolabeled precursors into cartilage macromolecules. Theophylline, in concentrations (0.1-0.5 mM) which raise intracellular cyclic AMP, also increases the incorporation of radiolabeled precursors into macromolecules. The data indicate that exogenous cyclic AMP and butyrylated cyclic AMP derivatives have paradoxical effects on cartilage macromolecule synthesis. Butyrylated cyclic AMP derivatives, not exogenous cyclic AMP, mimic the effects of intracellular cyclic AMP. Incubation of embryonic chicken cartilage with exogenous cyclic AMP results in the extracellular degradation of the cyclic AMP to adenosine. Adenosine (0.125 mM) inhibits precursor incorporation into cartilage macromolecules. The metabolism of exogenous cyclic AMP generates sufficient adenosine to account for the observed inhibitory effects of exogenous cyclic AMP on cartilage macromolecule synthesis. Butyrylated cyclic AMP derivatives are not degraded during incubation with cartilage. The data indicate that cartilage is a tissue in which the effect of cyclic AMP is to stimulate anabolic processes.     

Influence of monensin on biosynthesis, processing and secretion of proteodermatan sulfate by skin fibroblasts

The influence of monensin on biosynthesis, processing and secretion of proteodermatan sulfate from human skin fibroblasts was studied with the aid of a specific immunological procedure. Double-labeling experiments with [3H]leucine and [35S]sulfate indicated that monensin caused a dose-dependent parallel decrease of sulfate incorporation into total and of secretion of 3H-labeled proteodermatan sulfate. Compared with the untreated control, a greater proportion of incorporated [35S]sulfate than of incorporated [3H]leucine became secreted. Other monensin effects were a moderate intracellular accumulation of glycosaminoglycan-free core protein, a reduced chain length and a greatly reduced epimerization of D-glucuronic to L-iduronic acid residues. In contrast to the formation of N-acetylgalactosamine 4-sulfate residues 6-sulfation was not affected. Conversion of high-mannose-type oligosaccharides to complex-type N-glycans which normally occurred concomitantly with glycosaminoglycan biosynthesis was inhibited. Withdrawal of monensin made possible an additional sulfation of intracellularly accumulated proteodermatan sulfate. The newly formed sulfate esters did not cluster at the non-reducing ends of the glycosaminoglycan chains. Cells preexposed to monensin and labeled with [3H]glucosamine either in the absence or continuous presence of the drug incorporated similar amounts of 3H radioactivity into proteodermatan sulfate. The results suggest that epimerization of D-glucuronic acid residues and 4-sulfation occur predominantly in the trans cisternae of the Golgi apparatus whereas chain polymerisation and 6-sulfation take place predominantly in the cis Golgi complex.     

Undersulfated proteoglycans are secreted by cultured chondrocytes in the presence of the ionophore monensin

The monovalent ionophore, monensin, inhibits secretion of many different proteins from a wide variety of cells. The site of blockage is at the golgi complex. We have exposed chick embryo chondrocytes in suspension culture to monensin, at concentrations ranging from 10(-8) to 10(-6) M. At the higher concentrations, between 10(-7) and 10(-6) M, monensin inhibited secretion of type II procollagen, which accumulated in the chondrocytes. At these concentrations of the ionophore, proteoglycan synthesis was inhibited, as measured by radioactive serine incorporation into core proteins and by radioactive glucosamine or SO4 incorporation into glycosaminoglycans. However, at a monensin concentration of 3 x 10(-8) M, the incorporations of serine and glucosamine were close to normal while SO4 incorporation was at 30% of control values. The ratio of glucosamine to serine in pronase-released glycosaminoglycans from culture media was unaffected by 3 x 10(-8) M monensin but the sulfate to serine ratio decreased to 29% of control values. Examination of the glycosaminoglycans by gel filtration showed a progressive increase in Kav values as sulfation decreased. Undersulfation was demonstrated by radiochromatographic analysis of the digestion products following incubation with chondroitinase ABC. The composite results show that monensin interferes with sulfation of newly synthesized proteoglycans.     

Effects of 4-deoxy-L-threo-pentose, a novel carbohydrate, on neural cell proteoglycan synthesis and function.

A novel carbohydrate, 4-deoxy-L-threo-pentose (4-deoxyxylose), was synthesized by way of reductive dechlorination of a chlorodeoxy sugar. This carbohydrate, an analogue of xylose which is required for the initiation of glycosaminoglycan (GAG) synthesis, was used to explore the function of GAG side chains in neurite outgrowth on a laminin substrate. 4-Deoxyxylose inhibited the incorporation of 35SO4 into the GAGs of neuronal and astrocytic proteoglycans, with no effect being seen on the incorporation of [3H]glucosamine into proteoglycan. Direct analysis of the heparan sulphate fraction from such cells using nitrous acid digestion confirmed that the GAGs were undersulphated. No inhibition of either 35SO4 or [3H]glucosamine incorporation was observed in primary mouse hepatocytes exposed to 4-deoxyxylose. 4-Deoxyxylose produced a direct dose-dependent inhibition of neurite outgrowth by sensory neurons, and medium conditioned by neurons or astrocytes in the presence of 4-deoxyxylose displayed less laminin-complexed neurite-promoting activity than medium conditioned in its absence. These data suggest that 4-deoxyxylose inhibits neurite outgrowth by altering the sulphation of the GAGs of heparan sulphate proteoglycans.     

Regulation of heparan sulphate metabolism by adenosine 3′:5′-cyclic monophosphate in hepatocytes in culture

Freshly isolated rat hepatocytes maintained as monolayers in a serum-free medium synthesize sulphated glycosaminoglycans, most of which behave as heparan sulphate and are mainly distributed into intracellular compartments. Cyclic AMP, dibutyryl cyclic AMP, glucagon, noradrenaline, prostaglandin E(1), and theophylline, all drugs and hormones known to increase intracellular cyclic AMP concentrations, decreased the incorporation of (35)SO(4) (2-) into heparan sulphate of intra-, extra- and peri-cellular pools. The inhibition mediated by dibutyryl cyclic AMP was dose-dependent and observed as early as 2h after exposure to the drug. In the presence of 1mm-dibutyryl cyclic AMP, incorporation of (35)SO(4) (2-) or [(14)C]glucosamine into heparan sulphate was decreased to 40-50%, suggesting that dibutyryl cyclic AMP interfered with the synthesis of heparan sulphate. This was further supported by pulse-chase experiments, where dibutyryl cyclic AMP had no effect on the degradation of sulphated glycosaminoglycans. Heparan sulphates synthesized and secreted into the extracellular pool in the presence of dibutyryl cyclic AMP were smaller in size, whereas the degree of sulphation and molecular size of the heparan sulphate chains released by beta-elimination from these proteoglycans were not different from control values. In the presence of 1mm-cycloheximide, (35)SO(4) (2-) incorporation was decreased to 5%. Addition of p-nitrophenyl beta-d-xyloside, an artificial acceptor of glycosaminoglycan chain synthesis, enhanced this incorporation to 18%. Dibutyryl cyclic AMP did not have any inhibitory effect on the synthesis of chains initiated on p-nitrophenyl beta-d-xylosides. Incorporation of [(3)H]serine into heparan sulphate was not affected by dibutyryl cyclic AMP, whereas the degree of substitution of serine residues with heparan sulphate chains was less in heparan sulphate synthesized in the presence of dibutyryl cyclic AMP, suggesting that cyclic AMP exerts its effect on the metabolism of sulphated glycosaminoglycans by affecting the transfer of xylose on to the protein core.