Exogenous Sulfate Research Articles

Methionine and Sulfate Increase a Bowman−Birk-Type Protease Inhibitor and Its Messenger RNA in Soybeans

A soybean cotyledon cDNA library was screened for clones representing RNAs that were more abundant in cotyledons grown on methionine-supplemented medium than in those grown on unsupplemented (basal) medium. Three isolated clones encoded the Bowman−Birk protease inhibitor (BBPI). RNA gel blot hybridization confirmed that the BBPI mRNA level is increased by methionine (Met). Met and/or sulfate supplementation increased the amount of protease inhibitor activity in cultured cotyledons. In seeds of greenhouse-grown plants, protease inhibitor activity was increased by the addition of exogenous sulfate to the nutrient solution. Since BBPI and related low molecular weight proteinase inhibitors have an unusually high cyst(e)ine content, these compounds have been hypothesized to function in the storage of reduced sulfur. The data presented here support this hypothesis by providing evidence that additional sulfur as Met or sulfate increases the quantity of these proteins in seeds by increasing their mRNA levels. Keywords: Bowman−Birk; Glycine max; protease inhibitor; soybean; sulfate

Cell-Surface Heparan Sulfate Proteoglycan Mediates HIV-1 Infection of T-Cell Lines

The role of cell-surface proteoglycans in human immunodeficiency virus (HIV) infection of T-cell lines was investigated. HIV-1-susceptible lymphoblastic T-cell lines, MT-4 and H9, were analyzed for proteoglycan synthesis and found to make heparan sulfate (HS) and chondroitin sulfate proteoglycans. Enzymatic treatment of these cells with heparitinase, but not chondroitinase, significantly prevented HIV-1(IIIB) infection as measured by inhibition of cytopathicity, reverse transcriptase production, and syncytia formation. Sulfation of glycosaminoglycans HS chains was critical to viral entry as shown by inhibition of viral infection with sodium chlorate and its specific reversal with exogenous sulfate addition. Quantitation of direct virus binding to cells showed that treatment of cells with heparitinase inhibited HIV-1 binding to the T-cell surface. Exogenous HS added to cultures inhibited virus infection in a manner analogous to dextran sulfate, further supporting a functional role for HS in HIV-1 binding. These results provide evidence for participation of cell-surface HS proteoglycans in HIV-cell attachment and virus entry.

Conserved charge of glomerular and mesangial cell proteoglycans: possible role of amino acid-derived sulphate.

Sulphation of proteoglycans was studied in isolated glomeruli and cultured rat mesangial cells. Both preparations produced heparan, dermatan, and chondroitin sulphates, recoverable both from the tissue layers and the conditioned media. The proportion of heparan sulphate made by mesangial cells was independent of the age of the culture, but declined in later passage. These preparations differed from several other nontransformed cell types studied to date in that the degree of proteoglycan sulphation was independent of the concentration of inorganic sulphate provided. Even when no exogenous sulphate was added, sulphation-dependent charge density of newly synthesized proteoglycans was conserved. Both isolated glomeruli and cultured mesangial cells produced proteoglycans with 35S-labelled sulphate esters when [35S]methionine was provided as the sole source of labelled sulphate. Conversion of methionine to cysteine and subsequent oxidation of organic sulphate via the sulphinyl pyruvate pathway is the only mechanism known in eukaryotic cells that can account for this observation. We conclude that facile oxidation of sulphur-containing amino acids can contribute to sulphation of glomerular proteoglycans and may serve to sustain the charge density of these multifunctional molecules when the supply of inorganic sulphate is otherwise compromised.

Effects of detergents on the sulfation of chondroitin sulfate by sulfotransferase from chicken embryo epiphyseal cartilage

Homogenates of chicken embryo epiphyseal cartilage were prepared in buffered saline. The bulk of the sulfotransferase was found in the supernatant. However, small amounts of sulfotransferase were consistently found in the particulate fraction. Detergents (Triton X-100 and C12E8) added to the incubation mixture activated the sulfation of exogenous sulfate acceptor by the particulate fraction, whereas detergent treatment during homogenization increased sulfotransferase activity in the supernatant at the expense of that in the particulate fraction. Since sulfotransferase activities of the supernatant and particulate fractions had similar properties concerning specificity, affinity for chondroitin with different degrees of sulfation, thermal stability and activation by protamine, we conclude that the same enzyme is present in both fractions and that detergent activates indirectly, by releasing it to the medium.

Biosynthesis of heparin. Enzymatic sulfation of pentasaccharides.

Heparin-derived pentasaccharides with the general structures GlcN-GlcA/IdoA-GlcN-GlcA/IdoA-GlcN (where GlcA represents D-glucuronic acid and IdoA represents L-iduronic acid) and GlcNSO3-GlcA/IdoA-GlcNSO3-GlcA/IdoA- GlcNSO3 (where -NSO3 represents an N-sulfate group) were tested as exogenous sulfate acceptors in incubations with adenosine 3'-phosphate 5'-[35S]phosphosulfate and microsomal enzymes from a heparin-producing mouse mastocytoma. No transfer occurred to the N-unsubstituted pentasaccharide containing only L-iduronic acid, but the other three isomers incorporated various amounts of 35S, which was totally present in N-sulfate groups. After complete chemical N-sulfation, all four pentasaccharides served as acceptors in O-sulfotransferase reactions and incorporated from 20 to greater than 200 times as much radioactivity as did the nonsulfated parent compounds. The C-6 position of the internal glucosamine unit was labeled preferentially, irrespective of the structures of the adjacent hexuronic acid units. Significant 2-O-35S-sulfation of IdoA units occurred in both -IdoA-Glc-NSO3-GlcA- and -GlcA-GlcNSO3-IdoA- sequences, whereas no significant sulfation of GlcA residues was detected. The pentasaccharide GlcNSO3-GlcA-Glc-NSO3-GlcA-GlcNSO3 thus can be used as a selective substrate in assays for glucosaminyl-6-O-sulfotransferase activity. The antithrombin-binding region, essential for the blood anticoagulant activity of heparin, has been identified as a pentasaccharide sequence with the predominant structure GlcNR(6-OSO3)-GlcA-GlcNSO3(3,6-di-OSO3)-++ +IdoA(2-OSO3)-GlcNSO3(6-OSO3) (where R represents either a sulfate or an acetyl group and -OSO3 represents an O-sulfate/ester sulfate group, with locations of O-sulfate groups indicated in parentheses) (Lindahl U., Thunberg, L., Bäckström, G., Riesenfeld, J., Nordling, K., and Björk, I. (1984) J. Biol. Chem. 259, 12368-12376). The products of [35S]sulfate transfer to the pentasaccharide GlcNSO3-GlcA-GlcNSO3-IdoA-GlcNSO3 contained molecules with high affinity for antithrombin, corresponding to 0.3-0.5% of the total label. Structural analysis suggested the occurrence of O-[35S]sulfate groups at both C-6 of the nonreducing terminal glucosamine unit and C-3 of the internal glucosamine unit. No products with high affinity for antithrombin were formed from the pentasaccharides that had a different monosaccharide sequence than the binding region; and moreover, these oligosaccharides appeared unable to incorporate glucosaminyl 3-O-sulfate groups. These findings point to the importance of the uronic acid sequence in the generation of the antithrombin-binding region of heparin.

Effect of exogenous estrone sulfate on embryonic survival during asynchronous transfers in the pig

The effect of exogenous estrone sulfate (5 mg/day for 10 consecutive days starting on Day 10 after mating) on survival of embryos during asynchronous transfers was studied in Large White x Landrace gilts. Superinduction transfers were conducted by placing Day 4 embryos (younger) into mated Day-5 recipients (older) and vice versa. Treatment with estrone sulfate improved embryo survival in the transfer of younger embryos to recipients with a more developed uterine environment, but it did not affect the survival rate of older embryos in pregnant recipients. The results of the study also showed that when older embryos were transferred to a less developed uterine environment with or without estrone sulfate treatment they were better able to survine than younger embryos transferred to a more developed uterine environment.

Presence of unsulfated heparan chains on the heparan sulfate proteoglycan of human colon carcinoma cells: Implications for heparan sulfate proteoglycan biosynthesis

Abstract We provide direct evidence for the presence of unsulfated, but fully elongated heparan glycosaminoglycans covalently linked to the protein core of a heparan sulfate proteoglycan synthesized by human colon carcinoma cells. Chemical and enzymatic studies revealed that a significant proportion of these chains contained glucuronic acid and N-acetylated glucosamine moieties, consistent with N-acetylheparosan, an established precursor of heparin and heparan sulfate. The presence of unsulfated chains was not dependent upon the exogenous supply of sulfate since their synthesis, structure, or relative amount did not vary with low exogenous sulfate concentrations. Culture in sulfate-free medium also failed to generate undersulfated heparan sulfate-proteoglycan, but revealed an endogenous source of sulfate which was primarily derived from the catabolism of the sulfur-containing amino acids methionine and cysteine. Furthermore, the presence of unsulfated chains was not due to a defect in the sulfation process because pulse-chase experiments showed that they could be converted into the fully sulfated chains. However, their formation was inhibited by limiting the endogenous supply of hexosamine. The results also indicated the coexistence of the unsulfated and sulfated chains on the same protein core and further suggested that the sulfation of heparan sulfate may occur as an all or nothing phenomenon. Taken together, the results support the current biosynthetic model developed for the heparin proteoglycan in which unsulfated glycosaminoglycans are first elongated on the protein core, and subsequently modified and sulfated. These data provide the first evidence for the presence of such an unsulfated precursor in an intact cellular system.

Time-dependent, plasma-sulfate-independent kinetics of salicylamide in dogs

The mechanisms of the dose-dependent elimination kinetics of salicylamide in dogs were examined. Salicylamide was infused continuously over three consecutive 90-min periods. The rates of infusion during Periods I and III were the same. During Period II the infusion rate was 2.5-fold higher. Plasma concentrations of inorganic sulfate were kept constant by the administration of exogenous sulfate. The plasma concentrations of salicylamide, which reached steady state during Period I but not during II or III, were twice as high at the end of Period III than those at the end of Period I. Typical Michaelis-Menten kinetics do not explain these results. When salicylamide was given as 40 mg/kg single oral dose, clearance of an intravenous tracer dose of radiolabeled salicylamide was greatly reduced within 10 min but returned to baseline values by 240 min after the oral dose, despite persistently low plasma concentrations of inorganic sulfate. Therefore, dose- and time-dependent factors other than Michaelis-Menten kinetics, depletion of inorganic sulfate concentrations, and rate limitation of supply of "active sulfate" from plasma inorganic sulfate stores produce the dose- and time-dependent kinetics of salicylamide in the dog. Product inhibition of salicylamide sulfoconjugation remains a possible explanation.

Continuous glucose fermentation by an immobilized saccharolytic sulfate-reducer

A technique for the immobilization of a novel, strictly anaerobic saccharolytic sulfate-reducer, in alginate gel, was developed. Metabolites formed from glucose, both in the presence and in the absence of exogenous sulfate, in a continuously fed upflow-reactor at hydraulic retention times of between 12 hours and 1.3 hours included acetate, ethanol, lactate and hydrogen sulfide. Comparison of the data obtained during continuous fermentation of glucose and by free cells in batch cultures showed that this method of immobilizing strict anaerobic cells did not alter metabolite compositions meaningfully.

Isolation of saccharolytic dissimilatory sulfate-reducing bacteria

Four unidentified saccharolytic dissimilatory sulfate-reducing strains were isolated from an anaerobic digester. Cells were Gram-negative, motile, nonsporulating rods which differ markedly from known sulfate reducers especially with respect to carbon source utilisation and sulfur sources which can be reduced. The strains were capable of metabolising at least 26 out of 50 carbohydrates tested. Carbohydrates were, in the absence of exogenous sulfate, fermented to acetate, ethanol, lactate, carbon dioxide and hydrogen. In the presence of excess sulfate carbohydrates were fermented to acetate, ethanol, carbon dioxide, hydrogen and hydrogen sulfide, but lactate was not detected. An oxidized organic or inorganic sulfur source, including elemental sulfur, was not required as a prerequisite for growth on carbohydrates, Lactate was, in the presence of sulfate, converted to acetate, ethanol, carbon dioxide, hydrogen and hydrogen sulfide. In the absence of sulfate no lactate was utilised and no growth was observed.

Amino acid sulfur as a source of sulfate for sulfated proteoglycans produced by Swiss mouse 3T3 cells.

The uptake of sulfate by Swiss mouse 3T3 cells is blocked in the presence of 1 mM 4-isothiocyano-4'-acetamido-stilbene-2,2-disulfonic acid (SITS). In the absence of an exogenous source of sulfate, glycosaminoglycans produced by cells in the presence of the inhibitor are sulfated to the same extent as those produced by cells grown in its absence. The sulfate utilized in the absence of medium sulfate has been identified as that produced by the oxidation of the sulfur present in the amino acids cysteine and methionine. This finding indicates that, under conditions of restricted exogenous sulfate, caution is needed in the interpretation of data obtained with the use of [35S]methionine and/or [35S]cysteine as a general protein label, since both tyrosine and a variety of types of protein-linked carbohydrate chains may be modified by sulfation.

Developmental changes in glycosaminoglycan sulfotransferase activities in animal sera

Glycosaminoglycan sulfotransferase activities in sera during the prenatal and postnatal development of the ox, rat, and chicken were systematically measured with chemically desulfated cartilage chondroitin 4-sulfate, cornea keratan sulfate, and kidney heparan sulfate as exogenous sulfate acceptors and with [ 35S]sulfate-labeled 3′-phosphoadenosine 5′-phosphosulfate as a sulfate donor. The results of specificity studies and product analyses indicated that these enzymes introduce sulfates at position 6 of the internal N-acetylgalactosamine units of chondroitin, position 6 of the galactose units of keratan sulfate, and position 2 (an amino group) of the glucosamine units of heparan sulfate, respectively. The results of the enzyme assays indicated that (1) the three activities change in a development-associated manner in each animal species, (2) generally, the activities of the former two enzymes decrease with embryonic development and aging after birth, although in chicken serum they increase transiently at the late prenatal stage and decrease thereafter, and (3) the pattern of the changes in heparan sulfate sulfotransferase activity is species-dependent: the activity increases in the rat, decreases in the ox, and does not significantly change in the chicken during prenatal or postnatal development. These alterations may reflect development-associated biosynthesis of the corresponding glycosaminoglycans or maturation of the proteoglycans in some tissues.

Exogenous glycosaminoglycans stimulate hyaluronic acid synthesis by cultured human trabecular-meshwork cells

Addition of hyaluronic acid (50-200 micrograms ml-1) to the defined, serum-free media of cultured human trabecular-meshwork cells resulted in an increase of glycosaminoglycan (GAG) synthesis as measured by the incorporation of [14C]glucosamine. Lesser stimulatory effects were exerted by dermatan sulfate and chondroitin-4- or -6-sulfate. Nearly 90% of the labeled GAGs were found to be exerted into the medium and ea. 10% were associated with the cell layer. Mainly hyaluronic acid synthesis was stimulated by the exogenous GAGs. Analysis of the GAG-pattern revealed that exogenous hyaluronic acid stimulated hyaluronic acid synthesis (positive feedback), while exogenous dermatan sulfate and chondroitin sulfate had additional effects on chondroitin sulfate synthesis. Cell growth of these cultures, which exhibited a limited proliferative capacity (ca. 18 population doublings during their life span) was not affected by the GAG treatment. Thus, exogenous hyaluronic acid and to a lower degree dermatan sulfate or chondroitin sulfate appeared to interfere with the GAG-metabolism of these human trabecular-meshwork cells in culture.

Hydrogen metabolism and sulfate-dependent inhibition of methanogenesis in a eutrophic lake sediment (Lake Mendota)

Hydrogen metabolism was studied in anoxic sediments of the stratified Lake Mendota; using a method which allowed the measurement of in situ H2 concentrations and the headspace-free analysis of turnover of dissolved H2. Addition of sulfate resulted in partial but immediate inhibition of H2-dependent methanogenesis. Sulfate addition did not result in an immediate decrease in the steady state concentration of dissolved H2, nor did it significantly stimulate the rate constant of H2 turnover. Sulfate-induced decrease in dissolved H2 was only observed after prolonged incubation or when endogenous H2 production was stimulated by added glucose. The turnover of the in situ H2 accounted for only 14% of the H2-dependent methanogenesis from bicarbonate. While rates of methanogenesis increased during the season, rates of H2 turnover decreased, accounting for only 2% of the H2-dependent methanogenesis at the end of summer stratification. These observations indicate that increasing proportions of CH4 were formed from H2 being directly transferred in syntrophic methanogenic associations. The rapid inhibition of H2-dependent methanogenesis by exogenous sulfate may be explained at least partially by assuming methanogenic associations in which syntrophic sulfate reducers change their metabolism from fermentative H2 production to sulfate reduction.

The Hemlo gold deposit, Ontario: A geochemical and isotopic study

The Hemlo deposit, near Marathon, Ontario, is one of the largest gold deposits in North America. It is stratiform within Archean metamorphosed volcano-sedimentary rocks. The main ore zone is composed of pyritic, sericitic schist, and massive barite. This is the first report of stratiform barite in the Archean of North America, but other occurrences have since been found west of Hemlo. The mineralization is substantially enriched in Au, Mo, Sb, Hg, Tl and V and lacks carbonate. Because of metamorphism and deformation of the body its genesis is uncertain. 87Sr 86Sr of .7017 for barite from the deposit is similar to that of the sedimentary barite west of Hemlo and to initial ratios of contemporaneous volcanic rocks. At the base of the main ore zone, barite with δ 34 S of +8 to +12%. was deposited with ~0%. pyrite. Upward, both barite and pyrite get isotopically lighter, with minimum values for pyrite, to −17.5%, in non-baritic schist forming the upper part of the ore zone. In drill section, Au grades correlate with the isotopic composition of pyrite. This, and the association of fractionated sulphide with sulphate, suggests that Au, pyrite and barite were deposited contemporaneously. The linked, asymmetric distributions of S minerals and isotopic distributions, which are continuous from section to section, and the isotopic similarity of the Hemlo and western barites are consistent with a syngenetic depositional model. Two sources for the S minerals are considered. In the first, exogenous sulphate from a restricted basin were partially reduced in a geothermal system to form 34S-depleted sulphide. In the second, the sulphate and sulphide are of magmatic-hydrothermal origin. Sulphate and fractionated sulphide are uncommon in Archean rocks, but one or both occur with unusual frequency in major Archean gold deposits. Hydrothermal fluids of moderately high ƒ O 2 , containing sulphate and permitting isotopic fractionation between oxidized and reduced S species, may have favoured the dissolution, transport and precipitation of Au.

Control of l-amino acid oxidase in Neurospora crassa by different regulatory circuits

l-Amino acid oxidase is synthesized in Neurospora crassa in response to three different physiological stimuli: (i) starvation in phosphate buffer, (ii) mating, and (iii) nitrogen derepression in the presence of amino acids. During starvation in phosphate buffer, or after mating, l-amino acid oxidase synthesis occurred in parallel with that of tyrosinase. Exogenous sulfate repressed the formation of the two enzymes in starved cultures, but not in mated cultures. Sulfate repression was relieved by protein synthesis inhibitors, suggesting that the effect of sulfate required the synthesis of a metabolically unstable protein repressor. With amino acids as the sole nitrogen source only l-amino acid oxidase was produced. Under these conditions enzyme synthesis was repressed by ammonium and was insensitive to sulfate. Biochemical evidence suggested that the l-amino acid oxidase formed under the three different conditions was the same protein. Therefore, the expression of l-amino acid oxidase appeared to be under the control of least two regulatory circuits. One, also controlling tyrosinase, seems to respond to developmental signals related to sexual morphogenesis. The other, controlling other enzymes of the nitrogen catabolic system, is used by the organism to obtain nitrogen from alternative sources such as proteins and amino acids.

Defective PAPS-synthesis in epiphyseal cartilage from brachymorphic mice

Activity levels of sulfotransferases, requisite for the sulfation of chondroitin sulfate proteoglycan, were measured in cell-free homogenates prepared from neonatal epiphyseal cartilage of normal C57B1/6J or homozygous brachymorphic mice. In the presence of [ 35S]-PAPS only or [ 35S]-PAPS plus an exogenous sulfate acceptor, comparable amounts of 35 SO 4 2− were incorporated into chondroitin sulfate by the normal and mutant types of cartilage. In contrast, the mutant cartilage catalyzed the conversion of only 30% of the 35 SO 4 2− into chondroitin sulfate as compared to normal mouse cartilage when synthesis was initiated from ATP and H 2 35SO 4. These results suggest that the production of an undersulfated proteoglycan which has previously been reported in brachymorphic mice (Orkin, R.W. et al . (1976) Devel. Biol. 50 , 82–94) may result from a defect in the synthesis of the sulfate donor PAPS.

Influence of adjuvant arthritis on connective-tissue metabolism.

In rats with adjuvant arthritis, an analysis was made of the metabolism of sulfated proteoglycans, with particular attention to the dorsal skin and the extremities. Alterations were demonstrated in all the tissues examined. In the uninflamed dorsal skin, the uptake of exogenous sulfate was diminished. By contrast, in both hind limbs, at the injected and the non-injected site, the turnover of sulfated mucopolysaccharides was increased, above all in ligament and cartilage; the calcium content of the bone tissue of both hind legs was, however, not affected by the disease.

Biosynthesis of heparin. Solubilization and partial characterization of N- and O-sulphotransferases

Assay methods were developed enabling separate determination of N- and O-sulphotransferase activities in an enzyme preparation from mouse mastocytoma. N-Desulphoheparin and chemically N-acetylated heparan sulphate were used as specific exogenous sulphate acceptors in the transfer of [35S]sulphate residues from adenosine 3'-phosphate 5'-[35S]sulphatophosphate to amino and hydroxyl groups respectively. The resulting 35S-labelled polysaccharides were isolated as their cetylpyridinium complexes on filter paper. Sulphotransferases were solubilized from a mastocytoma microsomal fraction by treatment with detergent-alkali. The pH optimum for both enzymes was about 7.5 Km with regard to adenosine 3'-phosphate 5'-sulphatophosphate was estimated to be 2 X 10(-5) M for the N-sulphotransferase and 1 X 10(-4) M for the O-sulphotransferase(s). The enzymes required bivalent cations for maximum activity, Mn2+ stimulating both the N- and O-sulphotransferase four- to five-fold, whereas Ca2+ increased the N- but not the O-sulphotransferase activity. The O-sulphotransferase was found to be more sensitive to heat-inactivation, 60% of the activity being lost after 1 min at 50 degrees C, whereas only 15% of the N-sulphotransferase activity was lost. In contrast, the N-sulphotransferase was selectively inhibited (or inactivated) by NaCl; at 0.125 M-NaCl concentration the O-sulphotransferase activity was essentially unaffected, whereas the N-sulphotransferase activity was depressed by 80%. These results strongly indicate that N- and O-sulphate-transfer reactions should be ascribed to different enzymes, or, alternatively, to separate and independent active sites on the same enzyme molecule.

In Vivo Molybdate Inhibition of Sulfate Transfer to Porphyridium Capsular Polysaccharide

Active transport of exogenous sulfate into log phase cells of Porphyridium aerueineum followed Michaelis-Menten kinetics, and the apparent Km for sulfate transport is approximately 2.5 x 10(-6)m. Molybdate, also a group VI anion, is a competitive inhibitor of sulfate transport, and the inhibition is freely reversible. Once in the cell, molybdate depresses the rate of sulfate pool utilization by blocking sulfate transfer to polysaccharides destined for secretion to the cell surface. Specifically, molybdate inhibits the formation of adenosine 5'-phosphosulfate and in turn the formation of adenosine 3'-phosphate 5'-phosphosulfate, the activated donor for sulfate transfer reactions. Combined with the previous identification of adenosine 3'-phosphate 5'-phosphosulfate, this is taken as evidence that the adenosine 5'-phosphosulfate/adenosine 3'-phosphate 5'-phosphosulfate enzymatic sequence for sulfate activation and sulfate donor reactions is operating in Porphyridium. Thiosulfate is utilized as effectively as sulfate as both a sulfur source for growth and polysaccharide synthesis.