Microdetermination of inorganic sulfate using thin-layer plates

Inorganic sulfate was precipitated on cellulose thin-layer plates with the radioactive reagent, ¹³³BaCl₂. Excess reagent was removed by repeated washings with an acidic BaCl₂ solution. The residual activity was transferred to vials by cutting out the point of application and its immediate surroundings. Counting was performed in a scintillation well γ-counting system. The concentration-activity curve was linear.     

Evidence for two distinct intracellular pools of inorganic sulfate in Penicillium notatum.

A strain of Penicillium notatum unable to metabolize inorganic sulfate can accumulate sulfate internally to an apparent equilibrium concentration 10(5) greater than that remaining in the medium. The apparent Keq is near constant at all initial external sulfate concentrations below that which would eventually exceed the internal capacity of the cells. Under equilibrium conditions of zero net flux, external 35SO42- exchanges with internal, unlabeled SO42- at a rate consistent with the kinetic constants with the sulfate transport system. Efflux experiments demonstrated that sulfate occupies two distinct intracellular pools. Pool 1 is characterized by the rapid release of 35SO42- when the suspension of preloaded cells is adjusted to 10 mM azide at pH 8.4 (t 1/2, 0.38 min). 35SO42- in pool 1 also rapidly exchanges with unlabeled medium sulfate. Pool 2 is characterized by the slow release of 35SO42- induced by azide at pH 8.4 or unlabeled sulfate (t 1/2, 32 to 49 min). Early in the 35SO42- accumulation process, up to 78% of the total transported substrate is found in pool 1. At equilibrium, pool 1 accounts for only about 2% of the total accumulated 35SO42-. The kinetics of 35SO42- accumulation is consistent with the following sequential process: medium----pool 1----pool 2. Monensin (33 microns) accelerates the transfer of 35SO42- from pool 1 to pool 2. Valinomycin (0.2 microM) and tetraphenylboron- (1 mM) retard the transfer of 35SO42- from pool 1 to pool 2. At the concentrations used, neither of the ionophores nor tetraphenylboron- affect total 35SO42- uptake. Pool 2 may reside in a vacuole or other intracellular organelle. A model for the transfer of sulfate from pool 1 to pool 2 is presented.     

Interactions of inorganic phosphate and sulfate anions with collagen

We use direct infrared measurements to determine the number of binding sites, their dissociation constants, and preferential interaction parameters for inorganic phosphate and sulfate anions in collagen fibrils from rat tail tendons. In contrast to previous reports of up to 150 bound phosphates per collagen molecule, we find only 1-2 binding sites for sulfate and divalent phosphate under physiological conditions and approximately 10 binding sites at low ionic strength. The corresponding dissociation constants depend on NaCl concentration and pH and vary from approximately 50 microM to approximately 1-5 mM in the physiological range of pH. In fibrils, bound anions appear to form salt bridges between positively charged amino acid residues within regions of high excess positive charge. In solution, we found no evidence of appreciable sulfate or phosphate binding to isolated collagen molecules. Although sulfate and divalent phosphate bind to fibrillar collagen at physiological concentrations, our X-ray diffraction and in vitro fibrillogenesis experiments suggest that this binding plays little role in the formation, stability and structure of fibrils. In particular, we demonstrate that the previously reported increase in the critical fibrillogenesis concentration of collagen is caused by preferential exclusion of "free" (not bound to specific sites) sulfate and divalent phosphate from interstitial water in fibrils rather than by anion binding. Contrary to divalent phosphate, monovalent phosphate does not bind to collagen. It is preferentially excluded from interstitial water in fibrils, but it has no apparent effect on critical fibrillogenesis concentration at physiological NaCl and pH.     

Absorption, serum levels and urinary excretion of inorganic sulfate after oral administration of sodium sulfate in the conscious rat.

The absorption of inorganic sulfate after ingestion was investigated in rats. After oral administration of Na235SO4, 35S radioactivity was measurable in plasma already after 15 min and its plasma concentration reached a peak after about 1.5--2 h. The 35S-radioactivity excreted in urine during 24 h after ingestion of Na235SO4 together with varying amounts of unlabelled Na2SO4 (0.25--5.0 mmol Na2SO4 per rat) indicated an almost complete absorption of inorganic sulfate from the gastrointestinal tract. Determination of the inorganic sulfate concentration in rat serum 2 h after oral administration of 5.0 mmol Na2SO4 revealed a three-fold increase in serum sulfate concentration. The data suggest a rapid and almost complete absorption of inorganic sulfate after oral administration in the rat. Its importance in relation to the sulfate availability for sulfate conjugation of drugs is discussed.     

Influence of NSAID-induced inhibition of renal prostaglandin synthesis on inorganic sulfate clearance in rats.

The objective of the present investigation was to examine the influence of inhibition of renal prostaglandin synthesis on the renal clearance of inorganic sulfate, an electrolyte involved in the biotransformation of both exogenous and endogenous substrates. Homeostasis of inorganic sulfate is maintained predominantly by renal reabsorption in the proximal tubule. Using a crossover study design, the renal clearance of sulfate was assessed in conscious female Lewis rats during control periods and following the infusion of two structurally dissimilar nonsteroidal anti-inflammatory drugs, ibuprofen (IBU) and indomethacin (INDO). Animals were infused with IBU or INDO to achieve steady state concentrations of 59 +/- 8 micrograms/ml (mean +/- SD) of IBU and 22 +/- 3 micrograms/ml of INDO. At these serum concentrations, IBU and INDO produced greater than 80% decrease in the urinary excretion of prostaglandin (PG) E2. Treatment with either IBU or INDO significantly increased the renal clearance of sulfate, but did not alter the glomerular filtration rate as assessed by creatinine clearance. The role of prostaglandins in the effects of IBU and INDO on sulfate homeostasis was investigated by examining the influence of concomitant intraarterial PGE2 administration (infusion of 0.1 micrograms/min) on nonsteroidal anti-inflammatory drug-induced alterations in sulfate renal clearance. Although PGE2 alone did not significantly alter the renal clearance of inorganic sulfate or that of creatinine, the PGE2 infusion abolished the effects of IBU on sulfate renal clearance. Concomitant PGE2 administration also significantly increased the sulfate reabsorption rate in INDO-treated animals; other parameters were not significantly changed, although the fractional reabsorption of sulfate tended to increase (P = 0.17). The reason for the less pronounced effect on PGE2 on the INDO-sulfate interaction is as yet unknown, but may be partly due to additional mechanisms involved in the INDO-induced alterations in sulfate clearance. The results of these studies suggest that prostaglandin inhibition represents one mechanism whereby IBU can alter the renal clearance of inorganic sulfate.     

Sulfate conjugation in drug metabolism: role of inorganic sulfate

Conjugation with sulfate is a major pathway for the biotransformation of phenolic drugs in humans and many animal species. It is a process of limited capacity; the extent of sulfate conjugate formation and the metabolic clearance of drugs subject to conjugation with sulfate depend therefore on the dose, the dosage form, the route of administration, and the rate and duration of administration as well as on the pharmacokinetic parameters of competing processes. The effect of these variables is exemplified by the pharmacokinetics of salicylamide and acetaminophen in humans and rats. In our experience so far, the proximate cause of the nonlinear pharmacokinetics of sulfate conjugation of phenolic drugs is the limited availability and consequent depletion of inorganic sulfate. When this is prevented by direct or indirect (via sulfate donors such as N-acetylcysteine) repletion, the saturability of phenol sulfotransferase (EC 2.8.2.1) activity can become evident. The major mechanism of inorganic sulfate homeostasis is nonlinear renal clearance, which is due largely to saturable renal tubular reabsorption. Systemic depletion of inorganic sulfate secondary to utilization of this anion for the sulfation of drugs affects the availability of sulfate in the central nervous system and may, therefore, modify the disposition of certain neurotransmitters and other endogenous substances that are subject to sulfate conjugation.     

Expression of renal transport systems for inorganic phosphate and sulfate in Xenopus laevis oocytes.

As a first step within an experimental strategy (expression cloning) leading to the structural identification of the two brush-border membrane transport systems for phosphate and sulfate, we have studied the expression of Na(+)-dependent uptake of phosphate and sulfate in Xenopus laevis oocytes injected with rabbit kidney cortex poly(A)+ RNA (mRNA). Na(+)-dependent uptake of phosphate and sulfate was stimulated in a dose- and time-dependent manner up to 20-fold as compared to water-injected controls. After fractionation of the mRNA on a sucrose gradient (or by preparative gel electrophoresis), two neighboring fractions were identified to stimulate Na(+)-dependent phosphate uptake (average size: 3.4 kilobases) and Na(+)-dependent sulfate uptake (average size: 3.7 kilobases). The two transport systems can be discriminated by their inhibition by thiosulfate, which reduced sulfate uptake, but not phosphate uptake. Kinetic characterization of the expressed Na(+)-dependent transport activities results in properties similar to those described for transport activity in renal brush-border membrane vesicles.     

Automated determination of organic sulfur compounds. I. Spectrophotometric measurement of inorganic sulfate by low-pressure exchange chromatography

A method for determination of inorganic sulfate is described which represents the terminal step of an automated assay of organic sulfur compounds in biological fluids. Nanomole quantities of inorganic sulfate were applied to a barium chloranilate column. Corresponding amounts of chloranilate ion, released as a result of an exchange reaction, were then measured by uv absorption at 313 nm. The reproducibility and sensitivity of the method and a calibration curve are reported.     

Recombinant Rhodococcus sp. strain T09 can desulfurize DBT in the presence of inorganic sulfate

The putative Rhodococcus rrn promoter region was cloned from the benzothiophene desulfurizing Rhodococcus sp. strain T09, and the dibenzothiophene desulfurizing gene, dsz, was expressed under the control of the putative rrn promoter in the strain T09 using a Rhodococcus–E.coli shuttle vector. Strain T09 harboring the expression vector, pNT, could desulfurize dibenzothiophene in the presence of inorganic sulfate, methionine, or cysteine, while the Dsz phenotype was completely repressed in recombinant cells carrying the gene under the control of the native dsz promoter under the same conditions. Among the sulfur sources examined, no intermediates were detected and only the final desulfurized product, 2-hydroxy-biphenyl, was produced using ammonium sulfate as the sulfur source. Received: 4 December 2001 / Accepted: 7 January 2002     

Distribution of inorganic sulfate between plasma, liver, and bile

The distribution of ³⁵SO₄⁼ between inorganic and other forms in plasma, liver and bile of rats was studied by use of paper electrophoresis. The overall liver sulfate space varied from 50–100% but when determined for inorganic ³⁵SO₄⁼ was constant at 34%. This is considerably higher than that expected for passive distribution and suggests SO₄⁼ is actively transported into liver cells. Overall bile/plasma ratios were always greater than 1 while the ratio for inorganic sulfate was 0.44, a value consistent with the known bile/plasma electrical potential.     

Effects of organic sulfur compounds on extraction and determination of inorganic sulfate

The common methods for determining inorganic soil sulfate may be affected by the extraction of sulfate from organic sulfur compounds such as ester sulfates. In order to test this, various synthetic organic sulfur compounds (ranging from ester sulfates to sulfonates and C-bonded sulfur) were extracted with deionized water or with two common sulfate extractors (0.5 M NaHCO₃ and 0.02 M NaH₂PO₄). Similar amounts of dissolved sulfate were detected in all extracts of the aromatic ester sulfate hydroxyquinoline sulfate. Sulfate was not released from aliphatic ester sulfates or C-bonded sulfur. Ion chromatography was compared to a turbidimetric method for the determination of sulfate. The latter method, based on BaSO₄-precipitation, appeared to be unsuitable for determining sulfate in organically influenced solutions. Barium precipitated sulfate as well as ester sulfates. Furthermore, the photometry of BaSO₄ was influenced by specific absorption of dissolved organic compounds, leading to a misinterpretation of the sulfate concentration in the solution.     

Microassay of inorganic sulfate in biological fluids by controlled flow anion chromatography

The application of controlled flow anion chromatography to the assay of inorganic sulfate in biological fluids is described. The sulfate anion is separated from other anions by ion-exchange chromatography and quantitated conductimetrically. Coefficient of variance is 3.4%, about half that for the barium precipitation assay. Interference from heparin in plasma samples and unknown sources in tissue extract analysis is avoided. Sulfate levels in plasma are not different from those measured in serum after protein precipitation. Normal levels for sulfate concentration in human plasma, cerebrospinal fluid and hepatic tissue extract are reported.