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.     

Control of the synthesis, activity, and turnover of enzymes of sulfur metabolism in Neurospora crassa

The synthesis of aryl sulfatase, choline-O-sulfate permease, and two distinct sulfate permeases are repressed by methionine, but the activity of these enzymes is not subject to feedback inhibition. The permease species, but not aryl sulfatase, are also regulated by dynamic turnover, displaying a functional half-life of approximately 2 hr. The rate of turnover of these permeases is not influenced by the presence of the end product, methionine. Development of sulfate permease activity occurs only by de novo synthesis which requires both a lifting of methionine repression and a functional cys-3 product. The turnover system for sulfate permease is not present in dormant conidia but appears to be synthesized relatively rapidly during germination. Preexisting conidial sulfate permease is lost by turnover during germination and outgrowth into the mycelial phase, during which both permease species are synthesized anew, although the high affinity system contributes most of the total activity in growing mycelia.     

Regulation of sulfate transport in neurospora by transinhibition and by inositol depletion

Neurospora possesses two distinct sulfate transport systems, a low-affinity form (Permease I) which is the only type found in conidia, and a second species (Permease II) which predominates during the mycelial stage. Although methionine represses the synthesis of both of these permeases, inorganic sulfate only partially represses the mycelial form and does not affect the synthesis of Permease I. Both transport systems are also regulated by transinhibition. The transinhibition which occurs in mycelia is not due to an intracellular pool of inorganic sulfate, but is instead exerted by an early intermediate of the sulfate assimilatory pathway.The development of functional sulfate transport activity depends upon genetic and metabolic events which affect the cell membrane. The synthesis of sulfate permease activity in the inos mutant requires an exogenous supply of inositol. The effect of the cot mutant, which is thought to interfere with membrane synthesis, also prevents the development of sulfate permease at the restrictive temperature. The maintenance of pre-existing functional sulfate permease activity apparently also requires a continuous renewal of membrane components since withdrawal of inositol from inos mutants results in a rapid inactivation of transport activity.     

Isolation of UDP-N-acetylgalactosamine-6-sulfate sulfatase from quail oviduct and its action on chondroitin sulfate.

A sulfatase, which liberates sulfate from UDP-N-acetylgalactosamine-6-sulfate (the nucleotide occurring in quail egg white at high concentration), has been isolated from quail oviduct. The tissue also contained sulfatase activities for UDP-N-acetylgalactosamine-4-sulfate and nitrocatechol sulfate but these activities were removed from the 6-sulfatase fraction during purification. The UDP-N-acetylgalactosamine-6-sulfate sulfatase appears to be very closely related to a sulfatase activity for the non-reducing N-acetylgalactosamine-6-sulfate end group in chondroitin sulfate, $\text{i.}\text{e.}$ the two activities could not be separated from each other by various fractionation procedures and were affected in a parallel fashion by mild heating. The results, coupled with those of earlier studies on UDP-N-acetylgalactosamine-4-sulfate in hen oviduct, suggest that in avian oviducts a sulfation/desulfation system may exist wherein sulfated sugar nucleotides and sulfated glycosaminoglycans are involved as alternative or competitive substrates.     

Regulation of sulfate assimilation in Cytophaga johnsonae

We have studied the regulation of sulfate assimilation by the gliding bacterium Cytophaga johnsonae in which 20% of the total sulfur is in the sulfornate moiety of sulfonolipid. Added cystine inhibited sulfate uptake and growth with cystine as sulfur source resulted in a repression of sulfate uptake. However, low concentrations of cystine preferentially repressed the terminal reactions of sulfate assimilation responsible for cysteine synthesis while allowing the transport and activation of sulfate for sulfonolipid synthesis. The significance of this novel pattern of regulation in bacteria is discussed.     

Developmental regulation of choline sulfatase and aryl sulfatase in Neurospora crassa

Regulation of the synthesis of several enzymes of sulfur metabolism in Neurospora is a function of both metabolic regulation and the genetic control exerted by the cys-3 and scon regulatory genes. Additional control mechanisms appear to regulate the synthesis of choline sulfatase and aryl sulfatase in different developmental stages of the life cycle. The metabolic regulation of enzyme synthesis in conidia differs from that which occurs in the mycelial stage. During conidial germination and mycelial outgrowth, the synthesis of these enzymes is not coordinate but begins at different times and occurs at different rates. A rapid and early synthesis of choline sulfatase was observed during conidial germination under derepressing conditions; furthermore, synthesis of the enzyme also occurred for a brief period in germinating conidia even in the presence of repressing levels of sulfate. The results of this study suggest that several enzymes of sulfur metabolism are independently controlled by a developmental system which is superimposed upon the cys-3 regulatory mechanism. It was also found that choline sulfatase undergoes rapid turnover while aryl sulfatase is a stable species.     

High-Affinity Transport of Choline-O-Sulfate and Its Use as a Compatible Solute in Bacillus subtilis

We report here that the naturally occurring choline ester choline-O-sulfate serves as an effective compatible solute for Bacillus subtilis, and we have identified a high-affinity ATP-binding cassette (ABC) transport system responsible for its uptake. The osmoprotective effect of this trimethylammonium compound closely matches that of the potent and widely employed osmoprotectant glycine betaine. Growth experiments with a set of B. subtilis strains carrying defined mutations in the glycine betaine uptake systems OpuA, OpuC, and OpuD and in the high-affinity choline transporter OpuB revealed that choline-O-sulfate was specifically acquired from the environment via OpuC. Competition experiments demonstrated that choline-O-sulfate functioned as an effective competitive inhibitor for OpuC-mediated glycine betaine uptake, with a K_i of approximately 4 μM. Uptake studies with [1,2-dimethyl-¹⁴C]choline-O-sulfate showed that its transport was stimulated by high osmolality, and kinetic analysis revealed that OpuC has high affinity for choline-O-sulfate, with a K_m value of 4 ± 1 μM and a maximum rate of transport (V_max) of 54 ± 3 nmol/min · mg of protein in cells grown in minimal medium with 0.4 M NaCl. Growth studies utilizing a B. subtilis mutant defective in the choline to glycine betaine synthesis pathway and natural abundance ¹³C nuclear magnetic resonance spectroscopy of whole-cell extracts from the wild-type strain demonstrated that choline-O-sulfate was accumulated in the cytoplasm and was not hydrolyzed to choline by B. subtilis. In contrast, the osmoprotective effect of acetylcholine for B. subtilis is dependent on its biotransformation into glycine betaine. Choline-O-sulfate was not used as the sole carbon, nitrogen, or sulfur source, and our findings thus characterize this choline ester as an effective compatible solute and metabolically inert stress compound for B. subtilis. OpuC mediates the efficient transport not only of glycine betaine and choline-O-sulfate but also of carnitine, crotonobetaine, and γ-butyrobetaine (R. Kappes and E. Bremer, Microbiology 144:83–90, 1998). Thus, our data underscore its crucial role in the acquisition of a variety of osmoprotectants from the environment by B. subtilis.     

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.     

Ureidosuccinic acid permeation in Saccharomyces cerevisiae

Some strains of Saccharomyces cerevisiae exhibit a specific transport system for ureidosuccinic acid, which is regulated by nitrogen metabolism. Ureidosuccinic acid uptake occurs with proline but with ammonium sulfate as nitrogen source it is inhibited. The V for transport is 20–25 μmol/ml cell water per min. The apparent K_m is 3 · 10^-5. For the urep1 mutant (ureidosuccinic acid permease less) the internal concentration never exceeds the external one.In the permease plus strain ureidosuccinic acid can be concentrated up to 10 000 fold and the accumulated compound remains unchanged in the cells. Energy poisons such as dinitrophenol, carbonyl cyanide-m-chlorophenyl-drazone (CCCP) or NaN₃ inhibit the uptake. No significant efflux of the accumulated compound occurs even in the presence of these drugs.The specificity of the permease is very strict, only amino acids carrying an α-N-carbamyl group are strongly competitive inhibitors.The high concentration capacity of the cells and the lack of active exit of the accumulated compound support the hypothesis of a carrier mediated active transport system.     

Mycobacterium tuberculosis Rv3406 Is a Type II Alkyl Sulfatase Capable of Sulfate Scavenging

The genome of Mycobacterium tuberculosis (Mtb) encodes nine putative sulfatases, none of which have a known function or substrate. Here, we characterize Mtb’s single putative type II sulfatase, Rv3406, as a non-heme iron (II) and α-ketoglutarate-dependent dioxygenase that catalyzes the oxidation and subsequent cleavage of alkyl sulfate esters. Rv3406 was identified based on its homology to the alkyl sulfatase AtsK from Pseudomonas putida. Using an in vitro biochemical assay, we confirmed that Rv3406 is a sulfatase with a preference for alkyl sulfate substrates similar to those processed by AtsK. We determined the crystal structure of the apo Rv3406 sulfatase at 2.5 Å. The active site residues of Rv3406 and AtsK are essentially superimposable, suggesting that the two sulfatases share the same catalytic mechanism. Finally, we generated an Rv3406 mutant (Δrv3406) in Mtb to study the sulfatase’s role in sulfate scavenging. The Δrv3406 strain did not replicate in minimal media with 2-ethyl hexyl sulfate as the sole sulfur source, in contrast to wild type Mtb or the complemented strain. We conclude that Rv3406 is an iron and α-ketoglutarate-dependent sulfate ester dioxygenase that has unique substrate specificity that is likely distinct from other Mtb sulfatases.     

Ureidosuccinic Acid Uptake in Yeast and Some Aspects of Its Regulation

Ureidosuccinic acid (USA) is an intermediary product in pyrimidine biosynthesis. When proline was the sole nitrogen source, USA uptake occurred; however, when ammonium sulfate or glutamic acid was the nitrogen source, uptake was inhibited. Thus, a ura2 strain which does not synthesize USA would not grow when this substance was supplied on an ammonium sulfate or glutamic acid medium. Mutants are described in which uptake was constitutive on such a medium. Permeaseless mutants for USA have been found, and evidence is presented for permease specificity. It is shown that all constitutive mutants use the same transport system that is missing in the permeaseless mutant. These mutants are constitutive for two permeases: the specific USA permease and the general amino acid permease. The transport system studied here, like the general amino acid transport system, is regulated by nitrogen metabolism. These facts and others suggest that our permease constitutive mutants are impaired in nitrogen metabolism.     

The enzymic defect in Morquio's disease: the specificity of N-acetylhexosamine sulfatases.

Extracts of Morquio fibroblasts lack N-acetylgalactosamine 6-sulfate sulfatase activity, but exhibit normal levels of N-acetylglucosamine 6-sulfate sulfatase activity. Thus, the enzyme defective in Morquio's disease is a sulfatase specific for the 6-sulfate linked to sugars with the galactose configuration. Hydrolysis of ester sulfate by this enzyme is limited to 6-sulfate groups occurring at the non-reducing terminal.     

Uncoupler-Resistant Glucose Uptake by the Thermophilic Glycolytic Anaerobe Thermoanaerobacter thermosulfuricus (Clostridium thermohydrosulfuricum)

The transport of glucose across the bacterial cell membrane of Thermoanaerobacter thermosulfuricus (Clostridium thermohydrosulfuricum) Rt8.B1 was governed by a permease which did not catalyze concomitant substrate transport and phosphorylation and thus was not a phosphoenolpyruvate-dependent phosphotransferase. Glucose uptake was carrier mediated, could not be driven by an artificial membrane potential (Δψ) in the presence or absence of sodium, and was not sensitive to inhibitors which dissipate the proton motive force (Δp; tetrachlorosalicylanilide, N,N-dicyclohexylcarboiimide, and 2,4-dinitrophenol), and no uptake of the nonmetabolizable analog 2-deoxyglucose could be demonstrated. The glucokinase apparent K_m for glucose (0.21 mM) was similar to the K_t (affinity constant) for glucose uptake (0.15 mM), suggesting that glucokinase controls the rate of glucose uptake. Inhibitors of ATP synthesis (iodoacetate and sodium fluoride) also inhibited glucose uptake, and this effect was due to a reduction in the level of ATP available to glucokinase for glucose phosphorylation. These results indicated that T. thermosulfuricus Rt8.B1 lacks a concentrative uptake system for glucose and that uptake is via facilitated diffusion, followed by ATP-dependent phosphorylation by glucokinase. In T. thermosulfuricus Rt8.B1, glucose is metabolized by the Embden-Meyerhof-Parnas pathway, which yields 2 mol of ATP (G. M. Cook, unpublished data). Since only 1 mol of ATP is used to transport 1 mol of glucose, the energetics of this system are therefore similar to those found in bacteria which possess a phosphotransferase.     

Heparin trisaccharides with nonreducing 2-amino-2-deoxy-α-d-glucopyranosyl end-groups suitable as substrates for catabolic enzymes

Heparin trisaccharides having the sequence O-(2-amino-2-deoxy-α-d-glucopyranosyl)-(1→4)-O-α-l-idopyranosyluronic acid-(1→4)-2,5-anhydro-d-[1-³H]mannitol have been prepared, as substrate models for studying sulfatases of heparan sulfate catabolism, by α-l-iduronidase cleavage of previously reported heparin tetrasaccharides, with additional chemical and enzymic modification as required. Three series are described, including isomeric sulfate esters of that trisaccharide with no N-substituent, with N-acetyl substitution, and with N-sulfate substitution. New features of the substrate specificity of the hydrolases used, including iduronate sulfatase, α-l-iduronidase, glucosamine 6-sulfate sulfatase, and heparin sulfamidase, were observed, and simple procedures for partial purification of these hydrolases are reported. The structures assigned to the trisaccharides are supported by the mode of preparation, reactions, regularities in electrophoretic behavior, and identities of the products of deamination.     

Effect of sulfur supply on sulfate uptake,and alkaline sulfatase activity in free-living and symbiotic bradyrhizobia

The effect of sulfur limitation on sulfate transport and metabolism was studied in four bradyrhizobia strains using sulfur-limited and sulfur-excess chemostat cultures. Characteristics of bradyrhizobia associated with sulfurlimitation were determined and these parameters used to bioassay the sulfur status of bacteroids in nodules on sulfur adequate or sulfur deficient soybean and peanut plants. Sulfur-limited cells took up sulfate 16- to 100-fold faster than sulfur-rich cells. The sulfate-uptake system appeared similar in all strains with apparent K _m values ranging from 3.1 M to 20 M sulfate with maximum activities between 1.6 and 10 nmol·min^-1·mg^-1 protein of cells. Sulfate-limited cells of all strains derepressed the enzyme alkaline sulfatase in parallel with the derepression of the sulfate transport system. Similarly, the initial enzyme of sulfate assimilation (ATP sulfurylase) was fully derepressed in sulfur-limited cultures. Bacteroids isolated from sulfur adequate and sulfur deficient soybean and peanut possessed very limited sulfate uptake activity and low levels of activity of ATP sulfurylase as well as lacking alkaline sulfatase activity. These results indicate bacteriods have access to adequate sulfur to meet their requirements even when the host plant is sulfur-deficient.Abbreviations CCCP Carbonyl cyanide m-chlorophenylhydrazone - DCCD N,N-dicyclohexyl carbodiimide     

Synthesis of [75Se]trimethylselenonium iodide from [75Se]selenocystine

N-Acetylglucosamine-6-sulfate sulfatase activity was assayed by incubation of the radiolabeled monosaccharide N-acetylglucosamine [1-14C]6-sulfate (GlcNAc6S) with homogenates of leukocytes and cultured skin fibroblasts and concentrates of urine derived from normal individuals, patients affected with N-acetylglucosamine-6-sulfate sulfatase deficiency (Sanfilippo D syndrome, mucopolysaccharidosis type IIID), and patients affected with other mucopolysaccharidoses. The assay clearly distinguished affected homozygotes from normal controls and other mucopolysaccharidosis types. The level of enzymatic activity toward GlcNAc6S was compared with that toward a sulfated disaccharide and a sulfated trisaccharide prepared from heparin. The disaccharide was desulfated at the same rate as the monosaccharide and the trisaccharide at 30 times that of the monosaccharide. Sulfatase activity toward glucose 6-sulfate and N-acetylmannosamine 6-sulfate was not detected. Sulfatase activity in fibroblast homogenates with GlcNAc6S exhibited a pH optimum at pH 6.5, an apparent Km of 330 mumol/liter, and inhibition by both sulfate and phosphate ions. The use of radiolabeled GlcNAc6S substrate for the assay of N-acetylglucosamine-6-sulfate sulfatase in leukocytes and skin fibroblasts for the routine enzymatic detection of the Sanfilippo D syndrome is recommended.     

Chemical characterization and substrate specificity of rabbit liver aryl sulfatase A

Rabbit liver aryl sulfatase A (aryl-sulfate sulfohydrolase, EC 3.1.6.1) is a glycoprotein containing 4.6% carbohydrate in the form of 25 residues of mannose, seven residues of N-acetylglucosamine, and three residues of sialic acid per enzyme monomer of molecular weight 140 000. Each monomer consists of two equivalent polypeptide chains. The protein has a relatively high content of proline, glycine and leucine, and the amino acid composition of rabbit liver aryl sulfatase A is similar to that of other known liver sulfatases. Rabbit liver aryl sulfatase A catalyzes the hydrolysis of a wide variety of sulfate esters, although it appears possible that cerebroside sulfate is a physiological substrate for the enzyme because the Km is very low (0.06 mM). The turnover rate for hydrolysis of nitrocatechol sulfate or related synthetic substrates is much higher than the rate with most naturally occurring sulfate esters such as cereroside sulfate, steroid sulfates, L-tyrosine sulfate or glucose 6-sulfate. However, the turnover rate with ascorbate 2-sulfate is comparable to the rates measured using most synthetic substrates. These results are discussed in relationship to several previously described sulfatase enzymes which were claimed to have unique specificities.     

PERIODIC CHANGES IN RATE OF AMINO ACID UPTAKE DURING YEAST CELL CYCLE

Uptake of amino acids is a complex process but in cells growing with ammonia as sole nitrogen source the initial uptake rate of amino acids is a measure of the transport capacity of the uptake system (permease). In synchronous cultures of Saccharomyces cerevisiae amino acids were transported at all stages of the cell cycle. However, for any one amino acid the initial uptake rate was constant for most of the cycle and doubled during a discrete part of the cycle. Thus, for a variety of amino acids the functioning amino acid transport capacity of the membrane doubles once per cycle at a characteristic stage of the cycle. Arginine, valine, and phenylalanine exhibit periodic doubling of uptake rate at different stages of the cell cycle indicating that the transport of these amino acids is mediated by three different systems. Serine, phenylalanine, and leucine exhibit periodic doubling of the uptake rate at the same stage of the cycle. However, it is unlikely that serine and phenylalanine share the same transport system since the uptake of one is not inhibited by the other amino acid. This phenomenon is analogous to the periodic synthesis of soluble enzymes observed in S. cerevisiae.     

Regulation of Sulfate Assimilation in Plants: 7. Cysteine Inactivation of Adenosine 5'-Phosphosulfate Sulfotransferase in Lemna minor L

When 0.5 mm cysteine is added to cultures of Lemna minor L. growing with sulfate as the sole sulfur source, there is a rapid 80% loss of extractable adenosine 5′-phosphosulfate sulfotransferase. This loss is accompanied by an inhibition of sulfate uptake; however, lack of sulfate is not responsible for the decreasing adenosine 5′-phosphosulfate sulfotransferase activity.     

Morquio's syndrome: deficiency of a chondroitin sulfate N-acetylhexosamine sulfate sulfatase

The Morquio syndrome is a spondyloepiphyseal dysplasia characterized by excretion in urine of excessive amounts of keratan sulfate and chondroitin sulfate. To investigate the enzymic basis of this disease, assays for sulfatase were performed using chick embryo chondroitin sulfate and rat chondrosarcoma chondroitin 4-sulfate as substrates. The data obtained, using skin fibroblasts as an enzyme source, indicate that Morquio's syndrome is a deficiency of chondroitin sulfate N-acetylhexosamine sulfate sulfatase.