Utilization of sulfonic acids as the only sulfur source for growth of photosynthetic organisms

Growth on ethanesulfonic acid as the only sulfur source was found to occur in ten of the 14 green algae tested and in three of the ten cyanobacteria analyzed. Similar growth could not be demonstrated in the higher plant Lemna minor, or in tissue cultures of anise, sunflower and tobacco. Organisms growing on sulfonic acids as the only sulfur source developed an uptake system for ethanesulfonate found neither in algae growing on sulfate nor in algae unable to utilize sulfonic acids for growth. The development of sulfonate transport was not caused by substrate induction, but by conditions of sulfate starvation. The presence of this uptake system was always correlated with an increased sulfate-uptake capacity. Enhanced sulfate uptake was found in all S-deficient and sulfonate-grown cultures tested, indicating sulfate limitation as the regulatory signal. A lag period of 2–2.5 h after transfer to sulfate deprivation was needed for expression of both enhanced sulfate uptake and ethanesulfonate uptake in case of the green alga Chlorella fusca. It is speculated that the availability of sulfate (pool size) or a metabolic product in equilibrium with oxidized sulfur compounds (sulfate ester? sulfolipids?) controls sulfate and sulfonate uptake systems. The principle of (coordinated) derepression by starvation is discussed as a general strategy in photosynthetic organisms.     

5-Oxo-prolinase activity in tobacco suspension cultures: Regulation by sulfate nutrition

In heterotrophic and photoheterotrophic tobacco ( Nicotiana tabacum L., var. Samsun) suspensions cultured with growth-limiting amounts of sulfate, 5-oxo-prolinase activity declines at the same time as the growth rate of the cells decreases. However, 5-oxo-prolinase activity is reduced to a greater extent than growth. As a result, the specific activity of 5-oxo-prolinase also declines when sulfur is scarce. The decrease in both growth and 5-oxo-prolinase activity can be prevented by adding sulfate to the suspensions during exponential growth. Addition of sulfate after the exponential growth phase restored neither growth nor 5-oxo-prolinase activity. These observations show that 5-oxo-prolinase activity in tobacco cells is regulated by the sulfate supply in the medium. Such a regulation is an essential prerequisite, but not a proof, for a role of 5-oxo-prolinase as the rate-limiting factor in glutathione degradation.
During exponential growth the average specific activity of 5-oxo-prolinase in heterotrophic tobacco cells is twice as high as in photoheterotrophic cells. This difference is consistent with the idea that green cells are equipped for glutathione synthesis and export, and chloroplast-free cells for uptake and degradation of this peptide.     

Control of diaminopimelate decarboxylase by L-lysine during growth and sporulation of Bacilluscereus

l-Lysine caused repression of diaminopimelate decarboxylase synthesis in Bacillus cereus when grown in either a minimal defined medium (CDGS medium) or a complex defined medium (a modified lysine assay medium). When cells were grown in either of the two media, variations in the specific activity of the enzyme as a function of time were found to be correlated with the intracellular lysine pool size during growth. From all of the data presented, it seems reasonable to conclude that during growth the synthesis of diaminopimelate decarboxylase is probably regulated by the intracellular lysine pool size. The relationship between lysine pool concentration and the specific activity of the enzyme did not occur in sporulating cells. The specific activity of diaminopimelate decarboxylase started to decrease at the end of exponential growth and continued to decline until it became nondetectable at the time of dipicolinic acid synthesis and development of spore refractility. Throughout this time, the intracellular lysine pool size remained below that which allowed derepression of enzyme synthesis during exponential growth. The mechanism(s) responsible for the observed decrease in the specific activity of the enzyme at the end of exponential growth is unknown. A threefold rise in the intracellular diaminopimelic acid concentration occurred when there was little or no detectable enzyme activity at the time of dipicolinic acid synthesis. This accumulation of diaminopimelic acid may exert positive control on the synthesis of spore peptidoglycan, the major component of the spore cortex.     

Regulation of amino acid transport in growing cells of Streptomyces hydrogenans

(1) The active uptake of different amino acids by growing cells of Streptomyces hydrogenans was shown to be correlated with the physiological age of the cells. During the lag phase of growth the transport capacity increased and attained its highest level when the growth rate was maximum. During further growth the transport capacity declined progressively. The lowest transport activity was observed when the culture shifted into the stationary growth phase. (2) Such modulation of transport capacity was independent on the presence or absence of amino acids in the growth medium of the cells. (3) The size and the composition of the pool of free intracellular amino acids was also undergoing substantial variations during the growth cycle of the culture. In the lag phase, the levels of all amino acids decreased markedly and attained their lowest values at the end of this phase. During further growth the pool size was slowly replenished. (4) Removal of the pool resulted in a considerable gain of transport capacity. Therefore, it was concluded that active amino acid transport in growing Streptomyces hydrogenans is under feedback control by intracellular amino acids. (5) Quantitatively, the modulation of the pool size could not fully account for the variation of the transport capacity. Since a pool-independent stimulation of transport was found to be correlated with the increase of the growth rate of the cells, the possibility is discussed that the stimulation of transport is either due to increased levels of distinct RNA species, which might provide positive feedback signals for transport, or by increased rates of de novo synthesis of transport limiting proteins.List of Abbreviations AIB 2-aminoisobutyric acid - CM complete medium - MM mineral medium     

Interaction of sulfate and glutathione transport in cultured tobacco cells

Photoheterotrophic and heterotrophic suspension cultures of tobacco (Nicotiana tabacum L.) were grown with 1 mM glutathione (reduced; GSH) as sole source of sulfur. Addition of sulfate to both cultures did not alter the rate of exponential growth, but affected the removal of GSH and sulfate in different ways. In photoheterotrophic suspensions, addition of sulfate caused a decline in the net uptake of GSH, whereas sulfate was taken up by the green cells immediately. In heterotrophic suspensions, however, addition of sulfate did not affect the net uptake of GSH and sulfate was only taken up by the cells after the GSH supply in the medium had been exhausted. Apparently, GSH uptake in photoheterotrophic cells is inhibited by sulfate, whereas sulfate uptake is inhibited by GSH in heterotrophic cells. The differences in the effect of GSH on sulfate uptake in photoheterotrophic and heterotrophic tobacco suspensions cannot be attributed to differences in the kinetic properties of sulfate carriers. In short-time transport experiments, both cultures took up sulfate almost entirely by an active-transport system as shown by experiments with metabolic inhibitors; sulfate transport of both cultures obeyed monophasic Michaelis-Menten kinetics with similar app. K_m (photoheterotrophic cells: 16.0±2.0 M; heterotrophic cells: 11.8±1.8 M) and V_max (photoheterotrophic cells: 323±50 nmol·min^-1·g^-1 dry weight; heterotrophic cells: 233±3 nmol·min^-1·g^-1 dry weight). Temperature- and pH-dependence of sulfate transport showed almost identical patterns. However, the cultures exhibited remarkable differences in the inhibition of sulfur influx by GSH in short-time transport experiments. Whereas 1 mM GSH inhibited sulfate transport into heterotrophic tobacco cells completely, sulfate transport into photoheterotrophic cells proceeded at more than two-thirds of its maximum velocity at this GSH concentration. The mode of action of GSH on sulfate transport in chloroplast-free tobacco cell does not appear to be direct: a 14-h exposure to 1 mM GSH was found to be necessary to completely block sulfate transport; a 4-h time of exposure did not affect this process. Consequently, glutathione does not seem to be a product of sulfur metabolism acting on sulfate-carrier entities by negative feedback control. When transferred to the whole plant, the observed differences in sulfate and glutathione influx into green and chloroplast-free cells may be interpreted as a regulatory device to prevent the uptake of excess sulfate by plants.Abbreviations DCCD N,N-dicyclohexylcarbodiimide - DNP dinitrophenol - DW dry weight - FW fresh weight - GSH reduced glutathione     

Growth Kinetics of Thiobacillus thiooxidans on the Surface of Elemental Sulfur

The growth kinetics of Thiobacillus thiooxidans on elemental sulfur in batch cultures at 30(deg)C and pH 1.5 was studied by measuring the time courses of the concentration of adsorbed cells on sulfur, the concentration of free cells suspended in liquid medium, and the amount of sulfur oxidized. As the elemental sulfur was oxidized to sulfate ions, the surface concentration of adsorbed cells per unit mass of sulfur approached a maximum value (maximum adsorption capacity of sulfur particles) whereas the concentration of free cells continued to increase with time. There was a close relationship between the concentrations of free and adsorbed cells during the microbial sulfur oxidation, and the two cell concentrations were well correlated by the Langmuir isotherm with adsorption equilibrium constant K(infA) and maximum adsorption capacity X(infAm) of 2.10 x 10(sup-9) ml per cell and 4.57 x 10(sup10) cells per g, respectively. The total concentration of free and adsorbed cells increased in parallel with the amount of sulfate formed. The total growth on elemental sulfur gave a characteristic growth curve in which a linear-growth phase followed the period of an initial exponential phase. The batch rate data collected under a wide variety of inoculum levels (about 10(sup5) to 10(sup8) cells per ml) were consistent with a kinetic model assuming that the growth rate of adsorbed bacteria is proportional to the product of the concentration, X(infA), of adsorbed cells and the fraction, (theta)(infV), of adsorption sites unoccupied by cells. The kinetic and stoichiometric parameters appearing in the model were estimated from the experimental data, and the specific growth rate, (mu)(infA), and growth yield, Y(infA), were 2.58 day(sup-1) and 2.05 x 10(sup11) cells per g, respectively. The proposed model and the parameter values allowed us to predict quantitatively the surface attachment of T. thiooxidans cells on elemental sulfur and the bacterial growth in both initial exponential and subsequent linear phases. The transition from exponential to linear growth was a result of two competing factors: an increase in the adsorbed-cell concentration, X(infA), permitted a decrease in the unoccupied-site fraction, (theta)(infV).     

Assimilatory sulfur metabolism in marine microorganisms: characteristics and regulation of sulfate transport in Pseudomonas halodurans and Alteromonas luteo-violaceus.

Sulfate transport capacity was not regulated by cysteine, methionine, or glutathione in Pseudomonas halodurans, but growth on sulfate or thiosulfate suppressed transport. Subsequent sulfur starvation of cultures grown on all sulfur sources except glutathione stimulated uptake. Only methionine failed to regulate sulfate transport in Alteromonas luteo-violaceus, and sulfur starvation of all cultures enhanced transport capacity. During sulfur starvation of sulfate-grown cultures of both bacteria, the increase in transport capacity was mirrored by a decrease in the low-molecular-weight organic sulfur pool. Little metabolism of endogenous inorganic sulfate occurred. Cysteine was probably the major regulatory compound in A. luteo-violaceus, but an intermediate in sulfate reduction, between sulfate and cysteine, controlled sulfate transport in P. halodurans. Kinetic characteristics of sulfate transport in the marine bacteria were similar to those of previously reported nonmarine systems in spite of significant regulatory differences. Sulfate and thiosulfate uptake in P. halodurans responded identically to inhibitors, were coordinately regulated by growth on various sulfur compounds and sulfur starvation, and were mutually competitive inhibitors of transport, suggesting that they were transported by the same mechanism. The affinity of P. halodurans for thiosulfate was much greater than for sulfate.     

Genetic and metabolic control of sulfate metabolism in Neurospora crassa: A specific permease for choline-O-sulfate

Neurospora crassa can use choline-O-sulfate as its sole sulfur source; the utilization of this compound involves its entry followed by intracellular hydrolysis. Neurospora possesses a transport system for the uptake of choline-O-sulfate which is specific for the sulfate ester and does not transport, nor is it inhibited by, either choline or inorganic sulfate. Mutant strains of Neurospora that are unable to transport or grow on inorganic sulfate can, nevertheless, utilize choline-O-sulfate for growth and transport the intact organic sulfate at a normal rate. Methionine, which represses a number of enzymes of sulfur anabolism, also represses the synthesis of the specific permease for choline-O-sulfate. A regulatory gene, cys-3, which controls the synthesis of choline sulfatase, aryl sulfatase, and several other related enzymes, also regulates the synthesis of the choline sulfate permease. Evidence is presented that the activity of choline sulfate permease is also regulated by a turnover process, the transport system having a functional half-life of approximately 3 hr.This investigation was supported by Public Health Service Grant 1 RO1 GM-18642 from the National Institute of General Medical Services.     

Formation of -cyanoalanine by O-acetylserine sulfhydrylase

Cell-free extracts of Bacillus megaterium form beta-cyanoalanine (beta-CNA)-(14)C from Na(14)CN and l-cysteine, O-acetyl-l-serine or, to a lesser extent, l-serine. However, the presence of cyanide in the growth medium does not increase the capacity of cell extracts to catalyze the formation of beta-CNA from cysteine and cyanide. The formation of beta-CNA is readily detected in extracts of cells grown in synthetic media with sulfate or l-djenkolic acid as sulfur sources; such cells also exhibit an increased ability to form cysteine when compared with cells grown on cysteine as the sulfur source. beta-CNA formation could not be detected in extracts of cells grown on cysteine as the sulfur source. A 40-fold purification of the O-acetyl-serine sulfhydrylase resulted in the co-purification of the beta-CNA-forming activity. The sulfhydrylase and the beta-CNA-forming activity co-chromatographed on diethyl-aminoethyl cellulose and Sephadex G-100.     

Proline Accumulation in Maize (Zea mays L.) Primary Roots at Low Water Potentials (I. Requirement for Increased Levels of Abscisic Acid)

We have characterized sulfate transport in the unicellular green alga Chlamydomonas reinhardtii during growth under sulfur-sufficient and sulfur-deficient conditions. Both the Vmax and the substrate concentration at which sulfate transport is half of the maximum velocity of the sulfate transport (K1/2) for uptake were altered in starved cells: the Vmax increased approximately 10-fold, and the K1/2 decreased approximately 7-fold. This suggests that sulfur-deprived C. reinhardtii cells synthesize a new, high-affinity sulfate transport system. This system accumulated rapidly; it was detected in cells within 1 h of sulfur deprivation and reached a maximum by 6 h. A second response to sulfur-limited growth, the production of arylsulfatase, was apparent only after 3 h of growth in sulfur-free medium. The enhancement of sulfate transport upon sulfur starvation was prevented by cycloheximide, but not by chloramphenicol, demonstrating that protein synthesis on 80S ribosomes was required for the development of the new, high-affinity system. The transport of sulfate into the cells occurred in both the light and the dark. Inhibition of ATP formation by the antibiotics carbonylcyanide m-chlorophenylhydrazone and gramicidin-S and inhibition of either F- or P-type ATPases by N,N-dicyclohexylcarbodiimide and vanadate completely abolished sulfate uptake. Furthermore, nigericin, a carboxylate ionophore that exchanges H+ for K+, inhibited transport in both the light and the dark. Finally, uptake in the dark was strongly inhibited by valinomycin. These results suggest that sulfate transport in C. reinhardtii is an energy-dependent process and that it may be driven by a proton gradient generated by a plasma membrane ATPase.     

Characteristics of the sulfate requirement of propionic acid bacteria

The kinetics of sulfate assimilation by Propionibacterium shermanii was found to be peculiar. The assimilation and excretion of sulfate into the medium had an oscillatory character. Sulfate was shown to pass into the cell by active transport. Sulfate transport is described by the Michaelis--Menten kinetics. Thiosulfate and sulfite inhibit sulfate assimilation. Cysteine does not entirely inhibit sulfate assimilation by the cells. The system of sulfate transport was repressed by cysteine to a small extent. The intracellular pool of inorganic sulfate changed in the process of culture growth.     

Stimulation of h(2)s emission from pumpkin leaves by inhibition of glutathione synthesis

The effect of inhibitors of glutathione (GSH) synthesis, namely gamma-methyl glutamic acid, d-glutamic acid, cystamine, methionine-S-sulfoximine (MSX), buthionine-S-sulfoximine, and GSH itself, on the emission of H(2)S was investigated. All these compounds stimulated H(2)S emission from pumpkin (Cucurbita pepo L. cv Small Sugar Pumpkin) leaf discs in response to sulfate. MSX and GSH were the most effective compounds, stimulating H(2)S emission from leaf discs of mature pumpkin leaves by about 80% in response to sulfate. Both inhibitors did not appreciably enhance H(2)S emission in response to l-cysteine and inhibited H(2)S emission in response to sulfite.Treatment with MSX or GSH enhanced the uptake of sulfate by pumpkin leaf discs, but did not affect the incorporation of sulfate into reduced sulfur compounds. Inhibition of GSH synthesis by MSX or GSH caused an increase in the pool size of cysteine, and, simultaneously, reduced the incorporation of labeled sulfate into cysteine. The incorporation of labeled sulfate into the sulfite and sulfide pools of the cells are stimulated under these conditions.These observations are consistent with the idea that inhibition of GSH synthesis leads to an elevated cysteine pool that inhibits further cysteine synthesis. The H(2)S emitted under these conditions appears to arise from diversion of a precursor of the sulfur moiety of l-cysteine. Therefore, stimulation of H(2)S emission in response to sulfate upon inhibition of GSH synthesis may reflect a role of H(2)S emission in keeping the cysteine concentration below a critical level.     

Effect of cultural conditions on the concentrations of metabolic intermediates during growth and sporulation of Bacillus licheniformis.

Intracellular concentrations of adenine nucleotides and intermediates of the Embden-Meyerhof pathway and the tricarboxylic acid cycle have been determined during growth and sporulation of Bacillus licheniformis in a variety of different media. The ATP pool was independent of growth rate and nitrogen source, but the use of glucose as a carbon source resulted in a twofold elevation in the ATP pool during exponential growth. The intracellular phosphoenolpyruvate pool was at least twofold higher during gluconeogenesis than during glycolysis. The finding that the use of glutamate as the sole nitrogen source resulted in at least a fivefold elevation of the alpha-ketoglutarate pool suggests a role for alpha-ketoglutarate in the repression of the enzymes of the tricarboxylic acid cycle responsible for alpha-ketoglutarate synthesis. Not one of the metabolites assayed appears to function as a signal of the nutrient deprivation which accompanies the initiation of sporulation.     

Compartmentation of Sulfur Metabolites in Tobacco Cells : USE OF EFFLUX ANALYSIS

The distribution of sulfur-containing metabolites in cultured tobacco cells was determined by analyzing efflux kinetics. Transported sulfate rapidly labeled the cytoplasmic pools of sulfate (1 hour) and sulfur amino acids (6 hours). Excess sulfate and amino acids were transported into the vacuole. The size and distribution of the amino acid pool was not affected by increasing the sulfate content of the cells.     

Excretion of polyamines in alfalfa and tobacco suspension-cultured cells and its possible role in maintenance of intracellular polyamine contents

Changes in polyamines (PAs) in cells and cultivation media of alfalfa (Medicago sativa L.) and tobacco bright yellow 2 (BY-2) (Nicotiana tabacum L.) cell suspension cultures were studied over their growth cycles. The total content of PAs (both free and conjugated forms) was nearly 10 times higher in alfalfa, with high level of free putrescine (Put) (in exponential growth phase it represented about 65-73% of the intracellular Put pool). In contrast, the high content of soluble Put conjugates was found in tobacco cells (in exponential phase about 70% of the intracellular Put). Marked differences occurred in the amount of PAs excreted into the cultivation medium: alfalfa cells excreted at the first day after inoculation 2117.0, 230.5, 29.0 and 88.0 nmol g(-1) of cell fresh weight (FW) of Put, spermidine (Spd), spermine (Spm) and cadaverine (Cad), respectively, while at the same time tobacco cells excreted only small amount of Put and Spd (12.7 and 2.4 nmol g(-1) FW, respectively). On day 1 the amounts of Put, Spd, Spm and Cad excreted by alfalfa cells represented 21, 38, 12 and 15% of the total pool (intra- plus extra-cellular contents) of Put, Spd, Spm and Cad, respectively. In the course of lag-phase and the beginning of exponential phase the relative contents of extracellular PAs continually decreased (with the exception of Cad). On day 10, the extracellular Put, Spd, Spm and Cad still represented 11.3, 10.9, 2.1 and 27% of their total pools. The extracellular PAs in tobacco cells represented from day 3 only 0.1% from their total pools. The possible role of PA excretion into the cultivation medium in maintenance of intracellular PA contents in the cells of the two cell culture systems, differing markedly in growth rate and PA metabolism is discussed.     

Ion Composition of Tobacco Cells Cultured under Sulfur Deficiency

In both photoheterotrophic and heterotrophic tobacco cells areduced supply of sulfate in the medium did not alter the ratebut the duration of exponential growth. The higher the sulfatesupply in the medium the longer exponential growth proceeded.However, the ion composition of photoheterotrophic and heterotrophiccells was affected by sulfur deficiency in completely differentways. The dynamics in the K⁺-, Na⁺-, Mg²*-, nitrate-, phosphate-,and malate-con-tents of photoheterotrophic cells during growthwere not at all, or only slightly changed, when the sulfatesupply in the medium was reduced from 1.8mM to 1.2 mM, 0.6 mM,or 0.3mM. In heterotrophic tobacco suspensions, however, severesulfur deficiency caused K⁺, Na⁺, Mg²⁺, and malate to accumulateand nitrate to begin to accumulate earlier inside the cells.Addition of sulfate after 4 days to heterotrophic suspensionsgrown under sulfur-limiting conditions prevented the accumulationof these cations and anions. During the initial period of growthalso phosphate accumulated inside heterotrophic tobacco cellsto amounts found to be the higher the smaller the sulfate-contentof the media. Apparently, in photoheterotrophic tobacco cellsthe ion composition can homeostatically be regulated independentfrom the cells' sulfate supply, whereas the ion compositionof heterotrophic tobacco cells appears to be highly dependenton the sulfate supply of the cells. ⁴Present address: Fraunhofer Institut für AtmosphärischeUmwéltforschung, Kreuzeckbahnstr. 19, D-8100 Garmisch-Partenkirchen, F.R.G. (Received August 30, 1988; Accepted January 18, 1989)     

Interaction of sulfur and nitrogen nutrition in tobacco (Nicotiana tabacum) plants: significance of nitrogen source and root nitrate reductase

Abstract: The significance of root nitrate reductase for sulfur assimilation was studied in tobacco (Nicotiana tabacum) plants. For this purpose, uptake, assimilation, and long-distance transport of sulfur were compared between wild-type tobacco and transformants lacking root nitrate reductase, cultivated either with nitrate or with ammonium nitrate. A recently developed empirical model of plant internal nitrogen cycling was adapted to sulfur and applied to characterise whole plant sulfur relations in wild-type tobacco and the transformant. Both transformation and nitrogen nutrition strongly affected sulfur pools and sulfur fluxes. Transformation decreased the rate of sulfate uptake in nitrate-grown plants and root sulfate and total sulfur contents in root biomass, irrespective of N nutrition. Nevertheless, glutathione levels were enhanced in the roots of transformed plants. This may be a consequence of enhanced APR activity in the leaves that also resulted in enhanced organic sulfur content in the leaves of the tranformants. The lack of nitrate reductase in the roots in the transformants caused regulatory changes in sulfur metabolism that resembled those observed under nitrogen deficiency. Nitrate nutrition reduced total sulfur content and all the major fractions analysed in the leaves, but not in the roots, compared to ammonium nitrate supply. The enhanced organic sulfur and glutathione levels in ammonium nitrate-fed plants corresponded well to elevated APR activity. But foliar sulfate contents also increased due to decreased re-allocation of sulfate into the phloem of ammonium nitrate-fed plants. Further studies will elucidate whether this decrease is achieved by downregulation of a specific sulfate transporter in vascular tissues.     

Evidence for an intracellular sulfur cycle in cucumber leaves

H₂S emission from cucumber (Cucumis sativus L.) leaf discs supplied with L-cysteine in the dark is inhibited 80–90% by aminooxyacetic acid (AOA), an inhibitor of pyridoxal-phosphate dependent enzymes. Exposure to L-cysteine in the light enhanced the emission of H₂S in response to this sulfur source. Turning off the light reduced the emission of H₂S to the rate observed in continuous dark; turning on the light enhanced the emission of H₂S to the rate observed in continuous light. Therefore, in the light H₂S emission in response to L-cysteine becomes a partially light-dependent process. Treatment with cyanazine, an inhibitor of photosynthetic electron transport, reduced H₂S emission in the light to the rate observed in continuous dark, but did not affect H₂S emission in the dark. In leaf discs pre-exposed to L-cysteine in the light, treatment with cyanazine+ AOA inhibited the emission of H₂S in response to L-cysteine completely. Therefore, only part of the H₂S emitted in response to this sulfur source is derived from a light-independent, but pyridoxal-phosphate-dependent process; the balance of the H₂S emitted is derived from a light-dependent process that can be inhibited by cyanazine. When cucumber leaf discs were supplied with a pulse of L-[^35S]cysteine, radioactively labeled H₂S was emitted in two waves, one during the first hour of exposure to L-cysteine, and a second after 3–4 h; unlabeled H₂S, however, was emitted continuously. The second wave of emission of labeled H₂S was not observed in pulse-chase experiments in which sulfate or cyanazine were added to the treatment solution after 3 h of exposure to L-cysteine, or when the lights was turned off. The labeling pattern of sulfur compounds inside cucumber cells supplied with a pulse of L-[³⁵S]cysteine showed that the labeled H₂S released from L-cysteine partially enters first the sulfite, then the sulfate pool of the cells. The radioactively labeled sulfate, however, is not incorporated into L-cysteine, but enters the H₂S pool of the cells again. These observations are consistent with the idea of an intracellular sulfur cycle in plant cells. The L-cysteine taken up by the leaf discs seems to be desulfhydrated in a light-independent, but pyridoxal-phosphate-dependent process. The H₂S synthesized this way may be partially released into the atmosphere; the other part of the H₂S produced in response to L-cysteine may be oxidized to sulfite, then to sulfate, which is subsequently reduced via the light-depent sulfate assimilation pathway. In the presence of excess L-cysteine, synthesis of additional cysteine may be inhibited, and the sulfide moiety may be split off carrier bound sulfide to enter the H₂S pool of the cells again. It is suggested that the function of this sulfur cycle may be regulation of the free cysteine pool.Abbreviation AOA aminooxyacetic acid     

Derepression of asparaginase II during exponential growth of Saccharomyces cerevisiae on ammonium ion

The biosynthesis of asparaginase II in Saccharomyces cerevisiae is sensitive to nitrogen catabolite repression. In cell cultures growing in complete ammonia medium, asparaginase II synthesis is repressed in the early exponential phase but becomes derepressed in the midexponential phase. When amino acids such as glutamine or asparagine replace ammonium ion in the growth medium, the enzyme remains repressed into the late exponential phase. The three nitrogen compounds permit a similar rate of cell growth and are assimilated at nearly the same rate. In the early exponential phase the internal amino acid pool is larger in cells growing with glutamine or asparagine than in cells growing with ammonium sulfate as the sole source of nitrogen.