Chemically defined inducers of alkylsulphatases present in Pseudomonas C12B

When Pseudomonas C12B is grown on nutrient broth to the stationary phase, cell extracts contain two secondary alkylsulphatases (S1 and S2) active towards potassium decan-5-yl sulphate but not towards potassium pentan-3-yl sulphate and one primary alkylsulphatase (P1) active towards sodium dodecan-1-yl sulphate (sodium dodecyl sulphate). When 10mm-sodium hexan-1-yl sulphate is included in the nutrient broth an additional primary alkylsulphatase (P2) is produced. The S1, S2, P1 and P2 enzymes are also present in extracts of cells grown on broth containing the commercial detergent Oronite, together with an additional secondary alkylsulphatase (S3) active towards pentan-3-yl sulphate as well as decan-5-yl sulphate. The P2 primary alkylsulphatase can be induced by a number of primary and secondary alkyl sulphate esters but the induction of the S3 enzyme appears to be a more specific and complex process. Studies on the ability of different fractions separated from Oronite to act as inducers suggest that the combination of a long-chain secondary alkyl sulphate(s) and a long-chain secondary alcohol(s) is responsible for the appearance of the S3 enzyme. Potassium hexadecan-2-yl sulphate or potassium tetradecan-2-yl sulphate, in combination with either hexadecan-2-ol or tetradecan-2-ol, can serve as inducers for the enzyme. Some characteristics of these specific inducer systems have been elucidated.     

[35S]Thiosulphate oxidation by rat liver mitochondria in the presence of glutathione

1. Rat liver mitochondria incubated in oxygen with glutathione and [(35)S]-thiosulphate produced labelled sulphate. 2. Inner-labelled thiosulphate (S.(35)SO(3))(2-) was converted into [(35)S]sulphate more rapidly than outer-labelled thiosulphate ((35)S.SO(3))(2-). 3. Thiosulphate labelled in both sulphur atoms was formed during ((35)S.SO(3))(2-) oxidation; the outer sulphur atom before oxidation to sulphate was incorporated into the inner position. 4. A thiosulphate cycle in the metabolic pathway of sulphate formation in animal tissues is discussed.     

[35S]Thiosulphate oxidation by Thiobacillus strain C

1. Thiobacillus strain C oxidized [(35)S]thiosulphate completely to sulphate. 2. During thiosulphate oxidation [(35)S]sulphate was formed more rapidly from (S.(35)SO(3))(2-) than from ((35)S.SO(3))(2-). (35)S disappeared less rapidly from thiosulphate with ((35)S.SO(3))(2-) as substrate than with (S.(35)SO(3))(2-). 3. Thiosulphate labelled in both atoms was produced during ((35)S.SO(3))(2-) oxidation, but not during (S.(35)SO(3))(2-) oxidation. 4. No (35)S was precipitated as elementary sulphur either in the presence or absence of exogenous unlabelled sulphur. 5. During [(35)S]thiosulphate oxidation, appreciable quantities of [(35)S]trithionate accumulated and later disappeared. Other polythionates did not accumulate consistently. 6. [(35)S]Trithionate was formed initially at a greater rate from (S.(35)SO(3))(2-) than from ((35)S.SO(3))(2-), but subsequently at a similar rate from each. 7. Trithionate formed from (S.(35)SO(3))(2-) was labelled only in the oxidized sulphur atoms, but that formed from ((35)S.SO(3))(2-) was labelled in both oxidized and reduced atoms. The proportion of (35)S in the oxidized atoms increased as more trithionate accumulated. 8. The results eliminate some mechanisms of trithionate formation but are consistent both with a mechanism of thiosulphate oxidation based on an initial reductive cleavage of the molecule and with a mechanism in which thiosulphate undergoes an initial oxidative reaction.     

Carbon and sulphur utilization during growth of Pseudomonas fluorescens on potassium d-glucose 6-O-sulphate as the sole sulphur source

Pseudomonas fluorescens N.C.I.B. 8248 was adapted to grow on potassium d-glucose 6-O-sulphate as the sole carbon and sulphur source. Adapted bacteria grew optimally at 37 degrees C on 1.6% (w/v) sulphate ester and growth coincided with the disappearance of the ester from the culture medium at a rate of 2.4mg/h per ml. Three sulphated compounds were detected in the culture fluid at the termination of growth. One of these was present in traces only and has not been identified. The second was present in somewhat greater amounts and was identified as the 6-O-sulphate ester of d-gluconate, and the major metabolite was identified as d-glycerate 3-O-sulphate. Sulphur utilization by the organism was not associated with the appearance of a glycosulphatase enzyme in the cells. However, a novel enzyme system (or systems) was present that liberated inorganic (35)SO(4) (2-) ions from dipotassium d-gluconate 6[(35)S]-O-sulphate and from dipotassium dl-glycerate 3[(35)S]-O-sulphate. Activity towards the latter substrate could not be detected when the adapted or parent Pseudomonas strain was cultured on d-glucose and potassium sulphate as respective carbon and sulphur sources. Some properties of the enzyme acting on the glycerate ester are recorded.     

The metabolism of sodium cortisone 27-[35S]-sulphate in the rat

1. The metabolism of sodium cortisone 21-[(35)S]sulphate was investigated in rats. 2. Quantitative and qualitative experiments showed that substantial amounts of (35)SO(4) (2-) appeared in the urine of free-ranging rats receiving the ester. 3. Whole-body radioautograms indicated considerable biliary elimination of (35)S and also pointed to the liver as the site of metabolism. 4. When female rats with bile-duct cannulae received sodium cortisone 21-[(35)S]sulphate approx. 70% of the dose appeared in the bile as a doubly conjugated steroid (metabolite I). This metabolite was identified as 3alpha-(beta-d-glucopyranuronosido)- 17alpha-hydroxy-21-[(35)S]sulpho-oxy-5alpha-pregnane-11,20-dione. 5. When metabolite I was administered to a rat with a bile-duct cannula 90% of the dose appeared in the bile unchanged. After the administration (intraperitoneally or orally) of metabolite I to free-ranging rats considerable amounts of (35)SO(4) (2-) appeared in the urine. 6. The route by which (35)SO(4) (2-) might be produced from cortisone [(35)S]sulphate in free-ranging animals is discussed.     

The oxidation of cyst(e)ine by mast-cell tumour P815 in culture

1. Mast-cell tumour P815 cells oxidize [(35)S]cyst(e)ine to (35)SO(4) (2-). 2. Addition of cysteinesulphinate or sulphite decreases the formation of (35)SO(4) (2-); at the same time [(35)S]cysteinesulphinate or (35)SO(3) (2-) accumulates. 3. Extracts of P815 cells form sulphite from cysteinesulphinate and 2-oxoglutarate. The K(m) for cysteinesulphinate is 6.35mm and that for 2-oxoglutarate is 0.165mm. 4. Extracts oxidize sulphite to sulphate. 5. No formation of hydrogen sulphide from cyst(e)ine was detectable. 6. It is concluded that P815 cells oxidize cyst(e)ine to sulphate solely via cysteinesulphinate and sulphite. 7. The concentration of the enzymes catalysing this sequence is unaltered by several variations in the conditions of growth.     

The catabolism of intravenously injected heparan N-[35S]sulphate in the rat

The metabolic fate of heparan N-[(35)S]sulphate was studied in rats. Heparan sulphate was obtained from either bovine aorta or lung and labelled with (35)S by desulphation and subsequent resulphation in vitro. Experiments in which heparan N-[(35)S]sulphate was administered intravenously to either free-range or wholly anaesthetized rats with ureter cannulae established that substantial desulphation occurs in vivo, with elimination of inorganic [(35)S]sulphate in urine. Oligosaccharides labelled with (35)S, possible intermediates in heparan sulphate degradation, could not be detected in urine or blood. The general distribution of radioactivity after administration of heparan N-[(35)S]sulphate, as demonstrated by whole-body radioautography, suggested that desulphation was not restricted to one organ in particular. Support for this view was obtained in experiments in which heparan N-[(35)S]sulphate was administered to animals after the removal of kidneys, liver, spleen, pancreas or gastrointestinal tract. In all cases inorganic [(35)S]sulphate was still produced. The ability of rats of desulphate heparan N-[(35)S]sulphate was progressively impaired by increasing concentrations of heparin administered simultaneously. It was concluded that heparan sulphate is metabolized at a number of sites in the body by a sequence of degradative events leading to the formation of inorganic sulphate. It is also concluded that at least some of these events are common to heparan sulphate and heparin.     

Sulphate utilization in an aphid symbiosis

When two clones of Myzus persicae were maintained on a defined diet with inorganic sulphate as sole sulphur source, their growth and survival were inferior to that on diets containing the sulphur amino acid, methionine. This discrepancy is due, at least in part, to the phagostimulatory properties of methionine, which stimulated aphid feeding rate by 50–150%. Myzus persicae incorporated radioactivity from dietary [³⁵S]sulphate into protein and low molecular weight compounds, including cysteine and methionine. Two lines of evidence indicate that the mycetocyte-symbionts are responsible for the reductive assimilation of sulphate. (1) [³⁵S]sulphate incorporation is abolished by treatment of the aphids with the antibiotic chlortetracycline, which disrupts the symbionts; and (2) [³⁵S]sulphate is utilized by isolated embryos (which contain mycetocyte-symbionts but no gut flora) but not by isolated guts. Tracer studies suggest that 20% of dietary radiosulphur is translocated to the aphid tissues, and it is hypothesized that methionine may be the principal product released by the symbionts.     

Metabolism of sodium oestrone [35S]sulphate in the guinea pig

Intraperitoneal administration of sodium oestrone [(35)S]sulphate to male and female free-ranging guinea pigs is followed by excretion of most of the radioactivity mainly as inorganic [(35)S]sulphate in the urine within 72h. The remainder of the radioactivity in the urine was found in oestrone [(35)S]sulphate, two unidentified metabolites (A and B) and traces of oestradiol-17beta 3-[(35)S]sulphate. When injected intraperitoneally into animals with bile-duct and bladder cannulae, most of the dose was excreted in the bile. Unchanged oestrone [(35)S]sulphate was the main biliary component excreted in males and females, but the latter also excreted appreciable amounts of oestradiol-17beta 3-[(35)S]sulphate and metabolites A and B. The urine from these animals also contained these metabolites, inorganic [(35)S]sulphate and also oestrone [(35)S]sulphate, but in small amounts. Metabolite A was present only in samples from males. Whole body radioautography pinpointed the liver and kidney as the possible sites of metabolism of the ester. The ester underwent little desulphation in the isolated perfused female guinea-pig liver and in animals in which kidney function had been eliminated, and was excreted unchanged in the bile. These results and the observed low oestrogen sulphatase and arylsulphatase C activities found in guinea-pig liver and kidney support the view that the two enzymes are identical.     

Heparan sulphate sulphotransferase. Properties of an enzyme from ox lung

A heparan sulphate sulphotransferase was partially purified from an ox lung homogenate by (NH(4))(2)SO(4) precipitation. Various glycosaminoglycans were assayed as sulphate acceptors with this enzyme. The highest acceptor activity was obtained with desulphated heparin and heparan sulphate, which indicates that sulphate transfer may be to free amino groups of the substrate. Some heparan sulphate was (35)S-labelled by incubation with the enzyme and re-isolated. On treatment of this heparan [(35)S]sulphate with nitrous acid and separation of the degradation products on Sephadex G-15, a major peak of radioactivity was obtained, and identified as [(35)S]sulphate by high-voltage electrophoresis at pH5.3. The [(35)S]sulphate is believed to be derived from N-[(35)S]sulphated groups of heparan [(35)S]-sulphate. That the ox lung preparation contained an N-sulphotransferase was confirmed by the isolation of 2-deoxy-2-[(35)S]sulphoamino-d-glucose as the major product from the flavobacterial degradation of heparan [(35)S]sulphate.     

Purification, properties and substrate specificity of adenosine triphosphate sulphurylase from spinach leaf tissue

1. ATP sulphurylase was purified up to 1000-fold from spinach leaf tissue. Activity was measured by sulphate-dependent [(32)P]PP(i)-ATP exchange. The enzyme was separated from Mg(2+)-requiring alkaline pyrophosphatase (which interferes with the PP(i)-ATP-exchange assay) and from other PP(i)-ATP-exchange activities. No ADP sulphurylase activity was detected. 2. Sulphate was the only form of inorganic sulphur that catalysed PP(i)-ATP exchange; K(m) (sulphate) was 3.1mm, K(m) (ATP) was 0.35mm and the pH optimum was 7.5-9.0. The enzyme was insensitive to thiol-group reagents and required either Mg(2+) or Co(2+) for activity. 3. The enzyme catalysed [(32)P]PP(i)-dATP exchange; K(m) (dATP) was 0.84mm and V (dATP) was 30% of V (ATP). Competition between ATP and dATP was demonstrated. 4. Selenate catalysed [(32)P]PP(i)-ATP exchange and competed with sulphate; K(m) (selenate) was 1.0mm and V (selenate) was 30% of V (sulphate). No AMP was formed with selenate as substrate. Molybdate did not catalyse PP(i)-ATP exchange, but AMP was formed. 5. Synthesis of adenosine 5'-[(35)S]sulphatophosphate was demonstrated by coupling purified ATP sulphurylase and Mg(2+)-dependent alkaline pyrophosphatase (also prepared from spinach) with [(35)S]sulphate and ATP as substrates; adenosine 5'-sulphatophosphate was not synthesized in the absence of pyrophosphatase. Some parameters of the coupled system are reported.     

A study of the sulphur amino acids of rat tissues

1. In a study of the metabolism of l-[(35)S]methionine in vivo, the labelled sulphur compounds of rat liver and brain were separated first by ion-exchange chromatography into two fractions containing (i) free sulphur amino acids such as methionine, cystathionine, cyst(e)ine and homocyst(e)ine and (ii) glutathione. 2. Two-dimensional paper chromatography with butan-1-ol-acetic acid or propionic acid-water in the first direction and 80% acetone or acetone-ethyl methyl ketone-water in the second direction was found superior to other solvent systems for separating the sulphur amino acids. 3. At 10min. after injection of [(35)S]methionine only a small part of the (35)S was found combined in free methionine or other free sulphur amino acids. 4. Evidence was obtained of the presence of adenosyl[(35)S]methionine and adenosyl[(35)S]homocysteine in perchloric acid extracts of rat liver and brain. 5. The trans-sulphuration pathway was active in brain as well as in liver.     

Metabolism of sodium oestrone [35S]sulphate in the rat

Intraperitoneal, intravenous or oral administration of sodium oestrone [(35)S]-sulphate to male and female Medical Research Council hooded rats is followed by the rapid excretion of the bulk of the radioactivity in urine in the form of inorganic [(35)S]sulphate. Pre-treatment of rats with an antibiotic regimen does not affect the results except in the case of oral administration, when relatively large amounts of the dose are recovered as ester [(35)S]sulphate in faeces. Intravenous administration of the labelled ester to male and female rats with cannulae in bile duct and ureter gave results similar to those obtained with free-range animals. Only small amounts of radioactivity appeared in bile and this was mainly in the form of ester sulphate, including both oestrone [(35)S]sulphate and oestradiol-17beta 3[(35)S]-sulphate. Whole-body radioautography pinpointed the liver as the probable site of the desulphation of the sulphate ester and this was confirmed by liver and kidney perfusion experiments and by studies with rats in which kidney function had been eliminated by ligation of the renal pedicles.     

Purification and some properties of the D-lactate-2-sulphatase of Pseudomonas syringae GG.

A soil bacterium grown on propan-2-yl sulphate as sole source of carbon and sulphur yielded extracts containing an enzyme capable of liberating sulphate from racemic lactate-2-sulphate. The enzyme was purified to homogeneity by a combination of streptomycin sulphate precipitation of nucleic acids, batch treatment with DEAE-cellulose, and chromatography on columns of DEAE-cellulose, Sephacryl S-300 and butyl-agarose. The protein was monomeric with an Mr of 55 000-60 000. The enzyme activity was specific for D-lactate-2-sulphate (Km 6.6 nM; maximal specific activity 14.3 mumol/min per mg of protein) and showed no activity towards the L-isomer. The products of the enzyme's action were inorganic sulphate and D-lactate which were released in equimolar amounts and stoicheiometrically with the amount of ester hydrolysed. No L-lactate was formed. Retention of configuration implied cleavage of the O-S bond of the C-O-S ester link and this was confirmed by 18O-incorporation experiments in which 18O from 18O-enriched water in the incubation medium was incorporated exclusively and quantitatively into inorganic sulphate. Only two other esters (serine-O-sulphate and p-nitrophenyl sulphate) of a total of 29 compounds tested were substrates for the enzyme. D-Lactate, L-lactate-2-sulphate and the substrate analogues glycollate-2-sulphate and butyrate-2-sulphate were significantly inhibitory.     

The glycosulphatase of Trichoderma viride

The growth of the mould Trichoderma viride on a defined medium containing either potassium d-glucose 6-O-sulphate or potassium d-galactose 6-O-sulphate as sole sources of both carbon and sulphur is marked by the production of an enzyme system capable of liberating inorganic SO(4) (2-) ions from either of the sulphate esters. The enzyme is not produced when the organism is grown with glucose (or galactose) and potassium sulphate or with glucose and methionine as sole sources of carbon and sulphur. Experimental conditions are described whereby inorganic SO(4) (2-) ions liberated from potassium glucose 6-O-sulphate by the growing mould appear in the culture medium after a constant lag period of 21-24hr. The enzyme has been shown to be a simple glycosulphatase that is active towards the 6-O-sulphate esters of d-glucose and d-galactose but not towards potassium glucose 3-O-sulphate. The properties of the crude glycosulphatase show the enzyme to be appreciably different from analogous molluscan enzymes that can degrade monosaccharide sulphate esters.     

A novel assay for the biosynthesis of sulphated polysaccharide and its application to studies on the effects of somatomedin on cultured cells

1. A simple method is described for the determination of small amounts of [(35)S]sulphated polysaccharide with 95-100% recovery in the range from 0.3 to 150mug of polysaccharide. 2. The method is based on precipitation with cetylpyridinium chloride of polysaccharide samples applied to filter paper. It is not significantly disturbed by the presence in the sample of a large excess of inorganic (35)SO(4) (2-). 3. Sulphated glucosamino- and galactosaminoglycans may be determined separately by treatment of the sample with chondroitinase ABC. 4. The method is applicable to the assay of [(35)S]sulphated polysaccharide biosynthesis in cell cultures. A stimulation of sulphate incorporation obeying a linear dose-response curve, was demonstrated in somatomedin-incubated fibroblast and glia cell cultures. 5. The described system provides a new assay method for somatomedin. 6. The stimulatory effect of somatomedin on the synthesis of [(35)S]sulphated polysaccharide appeared to be general, rather than specific, for a particular type of polysaccharide.     

The metabolism of potassium dodecyl [35S]-sulphate in the rat

The metabolic fate of potassium dodecyl [(35)S]sulphate was studied in rats. Intraperitoneal and oral administration of the ester into free-ranging animals were followed by the excretion of the bulk of the radioactivity in the urine within 12hr., approximately 17% being eliminated as inorganic [(35)S]sulphate. Similar results were obtained in experiments in which potassium dodecyl [(35)S]sulphate was injected intravenously into anaesthetized rats with bile-duct and ureter cannulae. Analysis of urinary radioactivity revealed the presence of a new ester sulphate (metabolite A). This metabolite was isolated, purified and subsequently identified as the sulphate ester of 4-hydroxybutyric acid by paper, thin-layer and gas chromatography, by paper electrophoresis and by comparison of its properties with those of authentic butyric acid 4-sulphate. The identity of the metabolite was confirmed by isotope-dilution experiments. When either purified metabolite A or authentic potassium butyric acid 4[(35)S]-sulphate was administered to free-ranging rats the bulk of the radioactivity was eliminated unchanged in the urine within 12hr., approx. 20% of the dose appearing as inorganic [(35)S]sulphate. Whole-body radioautography and isolated-liver-perfusion experiments implicated the liver as the major site of metabolism of potassium dodecyl [(35)S]sulphate. It is suggested that butyric acid 4-sulphate probably arises by omega-oxidation of dodecyl sulphate to a fatty acid-like compound, which is then degraded by beta-oxidation.     

Primary alkylsulphatase activities of the detergent-degrading bacterium Pseudomonas C12B. Purification and properties of the P1 enzyme.

The P1 primary alkylsulphatase of Pseudomonas C12B was purified 1500-fold to homogeneity by a combination of streptomycin sulphate precipitation of nucleic acids, (NH4)2SO4 fractionation and chromatography on columns of DEAE-cellulose, Sephacryl S-300 and butyl-agarose. The protein was tetrameric with an Mr of 181000-193000, and exhibited maximum activity at pH 6.1. Primary alkyl sulphates of carbon-chain length C1-C5 or above C14 were not substrates, but the intermediate homologues were shown to be substrates, either by direct assay (C6-C9 and C12) or by gel zymography (C10, C11, C13 and C14). Increasing the chain length from C6 to C12 led to diminishing Km. Values of delta G0' for binding substrates to enzyme were dependent linearly on chain length, indicating high dependence on hydrophobic interactions. Vmax./Km values increased with increasing chain length. Inhibition by alk-2-yl sulphates and alkane-sulphonates was competitive and showed a similar dependence on hydrophobic binding. The P1 enzyme was active towards several aryl sulphates, including o-, m- and p-chlorophenyl sulphates, 2,4-dichlorophenyl sulphate, o-, m- and p-methoxyphenyl sulphates, m- and p-hydroxyphenyl sulphates and p-nitrophenyl sulphate, but excluding bis-(p-nitrophenyl) sulphate and the O-sulphate esters of tyrosine, nitrocatechol and phenol. The arylsulphatase activity was weak compared with alkylsulphatase activity, and it was distinguishable from the de-repressible arylsulphatase activity of Pseudomonas C12B reported previously. Comparison of the P1 enzyme with the inducible P2 alkylsulphatase of this organism, and with the Crag herbicide sulphatase of Pseudomonas putida, showed that, although there are certain similarities between any two of the three enzymes, very few properties are common to all three.     

Biochemical studies on the sulphated glycosaminoglycan fraction of skin fibroblasts cultured from a patient with the Hurler syndrome

1. The metabolism of the sulphated glycosaminoglycan fraction in cultured skin fibroblasts derived from a patient with the Hurler syndrome and from a normal subject was studied. Two labelled precursors, Na(2) (35)SO(4) and d-[2-(3)H]glucose, were used and their intracellular fates during uptake and ;chase' periods were assessed after separation of sulphated glycosaminoglycans from hyaluronic acid. After 4 or 8h of exposure to culture medium containing both labels, [(35)S]sulphate incorporation into the sulphated glycosaminoglycan fraction was twofold greater in Hurler-syndrome cells than in normal cells. At the same time, the rate of incorporation of [(3)H]glucose into the sulphated glycosaminoglycan fraction was approximately the same for both cell types. Consequently, an increased (35)S/(3)H ratio (nmol of [(35)S]sulphate incorporated/nmol of [(3)H]glucose incorporated) was observed for Hurler-syndrome cells compared with normal cells. 2. The results of ;chase' experiments revealed that although the expected loss and relative retention of labelled sulphate occurred in the sulphated glycosaminoglycan fraction of normal and Hurler-syndrome cells, both cell types retained all of their radioactivity derived from [(3)H]glucose. 3. After 34h exposure to a ;corrective-factor' preparation from urine, the sulphated glycosaminoglycan content (as hexosamine and [(35)S]sulphate) of the Hurler-syndrome cells approached normal values. At the same time, there was an increase in specific radioactivity of ;corrected' Hurler-syndrome cells.     

Inhibition of sulphur redistribution into new leaves of vegetative soybean by excision of the maturing leaf

When soybean plants are pulsed with [³⁵S]sulphate, label is subsequently redistributed from the roots to the leaves. This confounds studies to measure the redistribution of label from leaves. Accordingly, soybean plants ( Glycine max [L.] Merr. cv. Stephens) were grown in 20 μ M sulphate and a small portion of the root system (donor root) was pulsed with [³⁵S]sulphate for 24 h. After removing the donor root, the plants were transferred into unlabelled solution, either without sulphate (S20→SO) or with 20 μ M sulphate (S20→20) (intact plants). Also at this time, the expanding leaf (L3) was excised from half of the plants in each treatment (excised plants). Immediately after the pulse, only ca 15% of the label occurred in the roots and ca 40% in the expanding leaf, L3, mostly in the soluble fraction. In intact S20→20 plants, ³⁵S-label was exported from the soluble fraction of L3, mostly as sulphate, whilst L4 and L5 imported label. Similar responses occurred in S20→SO plants except that export of label from L3 was more rapid. Excision of L3 from S20→S20 plants inhibited labelling of leaves L4-L6 but not total sulphur, whereas in S20→SO plants, excision of L3 inhibited the import of both total sulphur and ³⁵S-label in leaves L4, L5 and L6. The data suggest that the soluble fraction of almost fully expanded leaves is an important reserve of sulphur for redistribution to growing leaves. The ³⁵S-label in the root system exhibited fluctuations consistent with its proposed role in the recycling of soluble sulphur from the leaves.