Convenient Isolation and Kinetic Mechanism of Glutathionylspermidine Synthetase from Crithidia fasciculata*

(Received for publication, December 2, 1996, and in revised form, March 5, 1997)

Kerstin Koenig Dagger , Ulrich Menge Dagger , Michael Kiess Dagger , Victor Wray Dagger and Leopold Flohé §

From the Dagger  Gesellschaft für Biotechnologische Forschung, Mascheroder Weg 1, D-38124 Braunschweig, Germany, the § Department of Physiological Chemistry, Technical University of Braunschweig, Mascheroder Weg 1, D-38124 Braunschweig, Germany

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES


ABSTRACT

Trypanothione, the essential metabolite in the oxidant defense system of trypanosomatids, is synthesized by two distinct proteins, glutathionylspermidine synthetase and trypanothione synthetase. Glutathionylspermidine synthetase was purified to homogeneity from the trypanosomatid Crithidia fasciculata by aqueous two-phase systems and chromatography. The enzyme showed a specific activity of 38 µmol of glutathionylspermidine formed per min per mg of protein. Its molecular mass was 78 kDa in SDS-polyacrylamide gel electrophoresis, and it appeared predominantly monomeric in native polyacrylamide gel electrophoresis and gel filtration. The isoelectric point was at pH 4.6, and the pH optimum was near 7.6. Partial amino acid sequencing revealed homology with, but low similarity to, the glutathionylspermidine synthetase/amidase of Escherichia coli, and amidase activity was not detected in glutathionylspermidine synthetase of C. fasciculata. The kinetics of trypanosomatid glutathionylspermidine synthetase revealed a rapid equilibrium random mechanism with limiting Km values for Mg2+-ATP, GSH, and spermidine of 0.25 ± 0.02, 2.51 ± 0.33, and 0.47 ± 0.09 mM, respectively, and a kcat of 415 ± 78 min-1. Partial reactions at restricted cosubstrate supply were not detected by 31P NMR, supporting the necessity of a quarternary complex formation for catalysis. ADP inhibited competitively with respect to ATP (Ki = 0.08 mM) and trypanothione exerted a feedback inhibition competitive with GSH (Ki = 0.48 mM).


INTRODUCTION

Glutathionylspermidine synthetase (GspS)1 catalyzes the first of two steps of trypanothione biosynthesis, the synthesis of glutathionylspermidine (Gsp) from GSH and spermidine with the consumption of ATP (1). Trypanothione (N1,N8-bis(glutathionyl)spermidine; TSH) is a metabolite unique to trypanosomatids such as Trypanosoma sp., Leishmania sp., and Crithidia fasciculata (2). These parasites comprise pathogens causing widespread and difficult to treat tropical diseases such as African sleeping sickness (Trypanosoma brucei gambiense or Trypanosoma brucei rhodesiense), Chagas disease (Trypanosoma cruzi), kala azar (Leishmania donovani), oriental sore (Leishmania tropica), and mucocutaneous leishmaniasis (Leishmania braziliensis). Others (e.g. Trypanosoma congolense) affect domestic animals, whereas C. fasciculata is pathogenic to insects only.

Since the discovery of TSH in 1985 (3, 4), the pathways for its synthesis and utilization have attracted considerable interest as potential targets for selective therapeutic intervention (5, 6). In all trypanosomatids, TSH substitutes for GSH in the defense against hydroperoxides and derived reactive oxygen species because of its ability to reduce peroxides either enzymatically (7-9) or spontaneously (10). It thereby protects the parasitic trypanosomatids, which apparently are deficient in catalase and glutathione peroxidases (11), against oxidative stress for instance during host-defense reactions (9, 12, 13). Trypanothione disulfide thus formed is reduced by the NADPH-dependent trypanothione reductase (14, 15), a flavoprotein homologous to glutathione reductase that, together with glutathione peroxidases (16, 17), constitutes a major part of the defense system of the host (18, 19). The precursor of TSH, Gsp, may have a distinct biological role. It was first identified in Escherichia coli (20), where it remains unprocessed to TSH due to the apparent lack of TSH synthetase. In E. coli, GspS, and consequently Gsp, is prominent in the stationary phase (20, 21). Similarly, in C. fasciculata, Gsp increases substantially during the transition from growth phase to stationary phase, while TSH simultaneously drops (22). These fluctuations of GSH conjugates or the associated variations in cellular spermidine levels have tentatively been implicated in growth regulation (2, 20, 21).

The first enzyme of TSH synthesis, GspS, has been isolated once in trace amounts from C. fasciculata (0.5 mg from 500 g, wet cell mass) and preliminarily characterized in terms of the apparent Mr, kinetic parameters, and substrate specificity (1). An enzyme catalyzing the analogous reaction in E. coli has recently been cloned. Surprisingly, this GspS also exhibits a substantial amidase activity with Gsp as substrate. The simultaneous catalysis of Gsp synthesis and breakdown results in an apparently futile ATP consumption, the biological role of which remains speculative (23, 24). Since E. coli does not produce TSH, its GspS obviously has to be seen in a biological context distinct from trypanosomal TSH metabolism, and also the structural and phylogenetic relationship of bacterial and trypanosomal GspS remains to be investigated.

Here we report a convenient isolation procedure for GspS from C. fasciculata that allows an in depth analysis of this enzyme. Various physicochemical parameters, preliminary amino acid sequence data, and the kinetic mechanism of the enzyme are presented.


EXPERIMENTAL PROCEDURES

Protein Determination

Protein concentrations were determined by the method of Bradford (25). Bovine serum albumin was used as a standard.

Enzyme Assays

The assays were carried out at 25.0 °C in a volume of 0.9 ml containing 50 mM bis-Tris-propane, 50 mM Tris, pH 7.5, 5 mM MgSO4, 1 mM EDTA, 5 mM DTT, 5 mM ATP, 10 mM GSH, and 10 mM spermidine (1). The assay for trypanothione synthetase (TS) was carried out as described by Smith et al. (1). Aliquots were taken after 20 min. For thiol analysis, a precolumn derivatization with the fluorescent thiol-specific reagent, monobromobimane (Calbiochem), was used as described previously (2). All samples for HPLC analysis were diluted 4-fold with water. Separation and analytical conditions were as described previously (26). HPLC analysis was performed with a Jasco-HPLC-system consisting of an autosampler (851-AS), a pump (PU-980), a ternary gradient unit (LG-980-02), and a highly sensitive fluorescence detector (FP-920), which enabled a precise analysis of the small product peak within numerous other and larger ones. An external standard (0.04 mM Gsp) was used for integration calibration of the samples. The malachite green colorimetric assay for liberation of inorganic phosphate (1) was used for fast detection of GspS activity during purification after column chromatography and for GspS localization on gels.

Purification of GspS

Production of Starting Material

C. fasciculata was grown in a medium previously described (27) in a 100-liter fermenter at 27 °C with continuous stirring (200 rpm) and aeration (0.1 volume/volume/min). Organisms were harvested in the late logarithmic growth phase by continuous flow centrifugation. The pellet was resuspended with 100 mM HEPES buffer (pH 7.5) containing 1 mM DTT and 1 mM MgSO4. After centrifugation, the cells were stored at -20 °C.

Extraction in Aqueous Two-phase Systems

250 g of cells were suspended in 250 ml of 20 mM bis-Tris-propane buffer, pH 7.5, disrupted by freezing in liquid nitrogen and thawing. The crude homogenate was subjected to an aqueous two-phase extraction at room temperature. All other operations were performed at 4 °C.

For extraction of GspS aqueous two-phase systems (total mass, 900 g) were prepared by weighing in concentrated solutions of the phase components and finally the crude extract (Fig. 1). A poly(ethylene glycol) (PEG)/phosphate system containing 7.5% (w/w) PEG6000, 13% (w/w) sodium-potassium phosphate, pH 7.0, and 40% crude homogenate (or water in the blank systems) was used. The mixture was gently shaken for 10 min at room temperature and separated by centrifugation at 5000 × g. The top phase was sucked off and applied to a bottom phase of a blank system. After mixing, centrifugation, and separation of the phases, the PEG-rich top phase of the second phase extraction was mixed with a blank bottom phase, adjusted to pH 6.0 with HCl. This third system was mixed again, centrifuged, and separated. Now the GspS was found in the phosphate-rich bottom phase.


Fig. 1. Extraction of glutathionylspermidine synthetase in aqueous two-phase systems. 1. system, GspS was extracted into the top phase of an aqueous two-phase system containing 7.5% (w/w) PEG6000 and 13% (w/w) sodium-potassium phosphate, pH 7.0. 2. system, the PEG-rich top phase of the first system containing GspS was applied to a bottom phase of an identical system containing water instead of cell lysate. 3. system, the top phase of the second phase system was added to an acidified bottom phase of a blank system. The GspS was now extracted into the phosphate-rich bottom phase.
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Diafiltration

The phosphate-rich third bottom phase and other pooled enzyme fractions were diafiltrated with a membrane with a cut-off of 30 kDa (Filtron Minisette) using a Pro Flux M12 diafiltrator (Amicon) at 0.2 megapascals and a 500-fold volume of 2 mM bis-Tris-propane buffer, pH 8.0.

Resource Q Chromatography

A BioLogic-System (Bio-Rad) was used at 4 °C for all chromatographies. The diafiltrated protein mixture was applied onto a Resource Q column (6 ml) (Pharmacia Biotech Inc.) equilibrated with 2 mM bis-Tris-propane buffer, pH 8.0. After washing with 10 column volumes of equilibration buffer, the bound proteins were eluted at a flow rate of 1 ml/min with a gradient of 0.0-0.4 M KCl (100% B) as follows: t = 0 min, B = 0%; t = 20 min, B = 15%; t = 40 min, B = 15%; t = 60 min, B = 30%; t = 120 min, B = 30%; t = 150 min, B = 100%. The GspS eluted at 0.27 M KCl, and the pooled active fractions were diafiltrated with 2 mM bis-Tris-propane buffer, pH 6.0.

Poros 20 Pi Chromatography

The diafiltrated proteins were applied onto Poros 20 Pi (0.46 × 10 cm, 1.7 ml) (Perseptive Biosystems) equilibrated with 2 mM bis-Tris-propane buffer, pH 6.0. After washing with 10 column volumes of equilibration buffer, bound proteins were eluted at a flow rate of 4 ml/min with a gradient of 0-1 M NaCl (100% B) as follows: t = 0 min, B = 0%; t = 8 min, B = 35%; t = 16 min, B = 35%; t = 17 min, B = 37%; t = 21 min, B = 37%; t = 25 min, B = 100%. GspS eluted at 0.7 M NaCl.

Poros 20 PE Chromatography

Pooled active fractions were adjusted to 1 M ammonium sulfate and applied onto a hydrophobic interaction chromatography column Poros 20 PE (0.46 × 10 cm, 1.7 ml) (Perseptive Biosystems) equilibrated with 20 mM bis-Tris-propane buffer, pH 8.0, containing 1 M ammonium sulfate, washed with 10 column volumes of equilibration buffer, and eluted with a linear gradient of 1-0 M ammonium sulfate and a flow rate of 4 ml/min over 7.5 min. GspS eluted at 0.75 M ammonium sulfate. Pooled active fractions were diafiltrated with 10 mM bis-Tris-propane buffer, pH 6.8.

Mono P Chromatography

The diafiltrated fraction was applied onto a Mono P HR 5/20 column (4 ml) (Pharmacia) for anion exchange chromatography. The column was equilibrated with 10 mM bis-Tris-propane buffer, pH 6.8. After washing with 10 column volumes of equilibration buffer, bound proteins were eluted with a gradient of 0-1 M NaCl (100% B) as follows: t = 0 min, B = 0%; t = 20 min, B = 25%; t = 40 min, B = 25%; t = 60 min, B = 50%; t = 80 min, B = 50%; t = 100 min, B = 100%. The flow rate was 1 ml/min. GspS eluted at 0.45 M NaCl.

Determination of Physical Parameters

Molecular Mass Estimation by Chromatography

Proteins were applied onto a gel permeation chromatography column, Superose 12 (HR 10/30) (Pharmacia), equilibrated with 20 mM bis-Tris-propane buffer, pH 7.5, containing 0.15 M NaCl, and eluted with a flow rate of 0.3 ml/min. Blue dextran (2,000 kDa), thyroglobulin (669 kDa), ferritin (440 kDa), beta -amylase (200 kDa), alcohol dehydrogenase (150 kDa), bovine serum albumin (67 kDa), and carbonic anhydrase (30 kDa) were used as standards.

Electrophoresis

The subunit molecular weight was determined by SDS-PAGE (28) using a PhastGel Gradient 8-25 (Pharmacia) with the following molecular mass standards: phosphorylase b (94 kDa), bovine serum albumin (67 kDa), ovalbumin (43 kDa), carbonic anhydrase (30 kDa), trypsin inhibitor (20.1 kDa), and alpha -lactalbumin (14.4 kDa).

The native molecular weight was determined by native PAGE using a PhastGel Gradient 8-25 (Pharmacia) with the same molecular mass standards and additionally thyroglobulin (669 kDa), ferritin (440 kDa), catalase (232 kDa), and lactate dehydrogenase (140 kDa).

The isoelectric point was determined by isoelectric focusing using a PhastGel IEF 3-9 (Pharmacia) with a broad pI calibration kit and by titration curve analysis with PhastGel IEF 3-9. The latter technique is a two-dimensional electrophoresis. In the first dimension, a pH gradient is generated. The gel is then rotated clockwise 90°, and the sample is applied perpendicular to the pH gradient across the middle of the gel (29).

For detection of GspS activity after native PAGE or isoelectric focusing, the gels were cut into two pieces; one was silver-stained for protein detection, and the second was incubated for 15 min at room temperature in a solution of 100 mM HEPES, pH 7.0, 5 mM MgSO4, 1 mM EDTA, 5 mM DTT, 10 mM GSH, 10 mM spermidine, and 2 mM ATP. After 15 min, 2.5 ml of a staining solution containing malachite green, ammonium molybdate, and Tween 20 (1) was added. Lanes containing active GspS showed a dark green color after few minutes.

The GspS content in partially purified samples was determined using SDS capillary electrophoresis (Bio-Rad) on the basis of the absorption at 280 nm and assuming an identical absorption coefficient for all proteins in the sample.

Amino Acid Sequencing

SDS-PAGE of purified GspS was performed at a constant current of 20 mA in a separating gel (7.5% T). For blotting, the proteins were transferred for 1.5 h onto a polyvinylidene difluoride membrane at 40 V/70 mA in a buffer containing 25 mM Tris base, 192 mM glycine, and 10% (v/v) methanol. The blot was stained with Coomassie Blue.

For peptide sequencing, the band corresponding to a molecular mass of 78 kDa was cut out. This material was washed and digested with endoproteinase Lys-C as described before (30) and separated by reversed-phase HPLC (30). Peptide peaks were detected at 214 nm and collected manually. Aliquots of 15-30 µl were applied directly to biobrene-coated, precycled glass fiber filters of a sequencer (Applied Biosystems 470A) with standard gas phase programs of the manufacturer.

Kinetic Analysis

All kinetic experiments were carried out at 25.0 °C in a volume of 0.9 ml containing 50 mM bis-Tris-propane, 50 mM Tris, pH 7.5, 1 mM EDTA, 5 mM DTT, and variable concentrations of ATP (0.10, 0.13, 0.18, 0.28, and 0.66 mM), GSH (0.36, 0.47, 0.66, 1.11, and 3.57 mM), and spermidine (0.36, 0.47, 0.66, 1.11, and 3.57 mM), respectively. The enzymatic tests for kinetic studies except the ADP inhibition studies were performed in the presence of phosphoenolpyruvate (10 mM) and pyruvate kinase (0.5 units). A fixed magnesium concentration of 5 mM and a GspS content of 0.072 mg (0.923 µM) was used. Aliquots were taken at 15 and 30 min. GspS activity was analyzed by product determination as described above.

31P NMR spectra were recorded on a Bruker ARX 400 NMR spectrometer (at 162 MHz and locked to the deuterium resonance of D2O) to detect potential partial reactions.

The experiments were carried out at 25.0 °C in a volume of 0.6 ml containing 50 mM bis-Tris-propane, 50 mM Tris, pH 7.5, 5 mM MgSO4, 1 mM EDTA, 5 mM DTT, in the presence of 20% D2O. Spectra were recorded at the beginning of the experiment and after the addition of the substrates (5 mM ATP, 10 mM GSH, and 10 mM spermidine).


RESULTS

Enzyme Purification

The purification strategy outlined under "Experimental Procedures" resulted in a GspS preparation with a specific activity of 37.6 units/mg at an overall yield of about 20%. The purification factor achieved was 12,500. As is seen from Table I, the phase distribution system applied proved to be highly efficient in enriching GspS.

Table I. Purification of glutathionylspermidine synthetase


Volume Protein Specific activity Purification factor Yield

ml mg units/mg %
Crude extract 380 7600.0 0.003 1 100
First extraction into top phase 170 221.0 0.092 31 107
Second extraction into top phase 170 119.0 0.129 43 81
Extraction into bottom phase 505 50.6 0.199 66 53
Diafiltration 1200 48.0 0.25 83 63
Resource Q 6 4.2 1.1 370 25
Poros 20 Pi 8 0.8 5.8 1943 24
Poros 20 PE 5 0.2 12.2 4067 13
Mono P 5 0.1 37.6 12533 19

The optimized procedure was based on a factorial design of phase compositions (31), i.e. PEG6000/phosphate (7.5/13% (w/w)), PEG4000/phosphate (8/14% (w/w)), PEG1550/phosphate (9/18% (w/w)), each tested at pH 4.0, 5.5, and 7.0 and containing 40% cell lysate. By centrifugation, the cell debris was concentrated in a gum-like interphase if the pH of the system was >= 5.5. A graphical evaluation of the experimental data (not shown) clearly demonstrated a significant increase in the partition coefficient of GspS with increasing pH and a decrease in the partition coefficient of the total protein with increasing molecular weight of PEG. The best system, containing 7.5% (w/w) PEG6000, 13% (w/w) phosphate, pH 7.0, yielded an extraction of GspS into the top phase (Fig. 1) with a purification factor of 30 in one step.

Some residual turbidity left in the top phase of the initial extraction could be eliminated by a second extraction step, mixing the primary top phase with a bottom phase of an identical blank system. By these systems, a proteolytic activity, as observed with casein yellow, and an ATPase activity were quantitatively removed by extraction into the bottom phases. Simultaneously, GspS was completely separated from TS activity. While GspS was recovered completely in the top phase, TS activity was extracted into the bottom phase (Fig. 1), but it proved to be unstable and was not purified further. This confirms, in contrast to previous assumptions (22), the existence of two distinct enzymes involved in trypanothione biosynthesis (1). After two extractions into top phases, GspS was essentially free of interfering enzymatic activities and could be precisely quantitated. The final chromatographic purification of GspS, however, was impaired by the high phosphate concentration and viscosity of the top phase in which the enzyme was dissolved. GspS was therefore extracted from the second top phase into the bottom phase of a third system by lowering its pH to 6.0 without loss of activity. The GspS in the phosphate-rich bottom phase was diafiltrated and then could be loaded onto a Resource Q column.

The specific activity of GspS obtained after additional chromatographic steps was about 6-fold higher than achieved before (1), and also the yields compared favorably with previous experience. In fact, GspS thus purified appeared homogeneous by SDS-PAGE (Fig. 2) and by titration curve analysis (Fig. 3).


Fig. 2. SDS-PAGE analysis of the glutathionylspermidine synthetase fractions during purification. Lane 1, SDS marker proteins; lane 2, pooled fractions after chromatography on Mono P; lane 3, pooled fractions after chromatography on Poros 20 PE; lane 4, pooled fractions after chromatography on Poros 20 Pi; lane 5, pooled fractions after chromatography on Resource Q.
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Fig. 3. Titration curve analysis of the homogeneous glutathionylspermidine synthetase. 1. dimension, isoelectric focusing, run without protein sample; 2. dimension, native PAGE.
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Enzyme Characterization

A subunit molecular mass of GspS of 78 kDa was estimated by SDS-PAGE, and an identical value was obtained by gradient gel electrophoresis of the native enzyme. In the latter case, the identity of the 78-kDa band with GspS was confirmed by activity staining, i.e. phosphate liberation upon incubation with Mg2+-ATP, GSH, and spermidine (not shown). Also, gel permeation chromatography on Superose 12 indicated a comparable molecular mass (79 kDa). A small activity peak eluted at about 170 kDa, suggesting a slight tendency of the enzyme to dimerize. In essence, however, GspS of C. fasciculata was present as a monomeric enzyme of 78 kDa. Its isoelectric point deduced from isoelectric focusing was at pH 4.6.

Functional characterization of GspS of C. fasciculata was performed with a 400-fold purified preparation, i.e. with the fraction obtained after step 6 in Table I, since the pure enzyme, even when stored at 4 °C and -20 °C, almost completely lost its activity within 1 day. According to purity analysis by capillary electrophoresis, the partially purified preparation contained 33% GspS. At this stage of purification, GspS activity was stable in 20 mM bis-Tris-propane, pH 8.0, and in the presence of 8 mM DTT for more than 2 months at -20 °C. However, it lost its activity within 1 day in the presence of 1 M phosphate and 1 M ammonium sulfate. At room temperature, the enzyme could be stored for more than 24 h without loss of activity, which guaranteed reliable functional studies at the temperature optimum between 25 and 30 °C. Biosynthetic activity required the presence of magnesium ions.

In partially purified GspS, we did not observe any TS activity, at a detection limit of >= 1% of the corresponding GspS rate. We could also exclude an amidase activity of C. fasciculata GspS, which had been described for the corresponding E. coli enzyme (23, 24), since Gsp was not hydrolyzed by C. fasciculata GspS under experimental conditions that would have detected a hydrolytic activity at a 1% level of the synthetase activity. TSH hydrolysis was also not detected (not shown). These findings contrast markedly with a relative amidase activity of 18% (pH 7.5) or 35% (pH 8.5) of the synthetase activity reported for E. coli GspS. Also, the pH optimum of the C. fasciculata enzyme (Fig. 4) is higher by nearly 1 pH unit (pH 7.6-7.8) than that of E. coli GspS (pH 6.8).


Fig. 4. pH optimum of glutathionylspermidine synthetase. Product formation of Gsp was analyzed as described under "Experimental Procedures." Values are means ± S.D. from two independent measurements done at 10 and 20 min.
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Amino Acid Sequencing

As already observed by Smith et al. (1), N-terminal amino acid sequencing proved unsuccessful, obviously due to an N-terminal blocking group. After proteolytic cleavage with endoproteinase Lys-C, however, a total of 11 peptides could be recovered from HPLC in a quality to allow sequencing. Of these peptides, seven could unambiguously be aligned to the deduced GspS sequence of E. coli recently published by Bollinger et al. (23) (Table II). GspS of E. coli and of C. fasciculata thus appeared to be phylogenetically related. However, based on the limited sequence information, the sequence similarity between these enzymes, with only 40% identity, appears rather low.

Table II. Peptides of glutathionylspermidine synthetase from Crithidia fasciculata

The amino acid numbering corresponds to the E. coli sequence (23). *, identical amino acids; +, similar amino acids found in GspS from E. coli. The amino acid numbering corresponds to the E. coli sequence (23). *, identical amino acids; +, similar amino acids found in GspS from E. coli.
(10)VPFGEVQGYAPGHIPAYSNK(29)
+*** + ***** + +**
133SIITGLDSPFAAI(145)
*** *   + *
(191)TYEPTE(196)
* **
(202)NEIPRPLTHK(211)
  **      *    +
(227)LDLNDPAE(234)
**    **++
(500)ILPIIYHNHPDHPAILRAE(518)
****++      *  *    +*    +
(535)IVGRVGRNVTITDG(548)
*+**  *  *+  +

Kinetic Pattern

The analysis of the kinetic mechanism by steady-state kinetics were performed by means of direct product (Gsp) detection at fixed time points. The time points were set to yield less than 15% consumption of the limiting substrate but more than 0.002 mM Gsp for a reliable quantification. In the beginning, nonlinear Lineweaver-Burk plots were obtained that could be attributed to product (ADP) inhibition (see below) and, at an ATP concentration above 1 mM, also to substrate inhibition (not shown). When ADP accumulation was avoided by coincubation with phosphoenolpyruvate/pyruvate kinase and the concentrations of ATP were kept constant at levels below 1 mM, linear double-reciprocal plots were observed. Fig. 5, A-C, illustrates enzyme-normalized Lineweaver-Burk plots, each showing the rate dependence of the variable substrate at five fixed variable concentrations of the cosubstrate and a fixed level of the third substrate. Hereby Mg2+-ATP was considered as a single substrate, since an excess of Mg2+ (5 mM) over ATP (maximum of 0.66 mM) guaranteed complete ATP complexation. From this set of primary data, the secondary and tertiary plots could be derived to fit the general Dalziel equation for three-substrate reactions (32).
<FR><NU>e</NU><DE>V<SUB>o</SUB></DE></FR>=&phgr;<SUB>o</SUB>+<FR><NU>&phgr;<SUB><UP>A</UP></SUB></NU><DE>[<UP>A</UP>]</DE></FR>+<FR><NU>&phgr;<SUB><UP>B</UP></SUB></NU><DE>[<UP>B</UP>]</DE></FR>+<FR><NU>&phgr;<SUB><UP>C</UP></SUB></NU><DE>[<UP>C</UP>]</DE></FR>+<FR><NU>&phgr;<SUB><UP>AB</UP></SUB></NU><DE>[<UP>A</UP>][<UP>B</UP>]</DE></FR>+<FR><NU>&phgr;<SUB><UP>AC</UP></SUB></NU><DE>[<UP>A</UP>][<UP>C</UP>]</DE></FR>+<FR><NU>&phgr;<SUB><UP>BC</UP></SUB></NU><DE>[<UP>B</UP>][<UP>C</UP>]</DE></FR>+<FR><NU>&phgr;<SUB><UP>ABC</UP></SUB></NU><DE>[<UP>A</UP>][<UP>B</UP>][<UP>C</UP>]</DE></FR>+<UP>etc</UP>. (Eq. 1)
All pertinent kinetic coefficients and constants describing the catalytic mechanism could be deduced. Even by inspection of the primary plots, an enzyme substitution or "ping-pong" mechanism could be excluded, since the slopes were clearly convergent. Fitting the experimental data to the general Dalziel equation yielded values significantly different from zero for all individual terms, thus ruling out a compulsory order mechanism. We therefore have to classify the kinetic mechanism of GspS as an equilibrium random order mechanism. Whether the complexation of the individual substrates occurs absolutely independently of each other or whether the binding substrates mutually affect affinities of cosubstrates is less easily decided. The apparent Km values for the different substrates, however, are not significantly affected by the concentrations of the respective cosubstrates. Consequently, the deduced dissociation constants of the corresponding binary, ternary, and quarternary complexes are very close for a given substrate and not significantly different (Table III). This would indeed imply a mutually independent random addition of substrates. However, with regard to the inevitable scatter of data, the possibility cannot be excluded that some route leading to the quarternary complex is slightly favored. However, a rapid equilibrium random order mechanism, as depicted in Fig. 8, conforms best to the experimental data. Based on this assumption, the limiting Km values are defined as the dissociation constants of the quarternary complexes, numerically 0.25 ± 0.02, 2.51 ± 0.33, and 0.47 ± 0.09 mM for Mg2+-ATP, GSH, and spermidine, respectively. The rate-limiting velocity constant can then be calculated to be k = 1/phi 0 = 415 ± 78 min-1.


Fig. 5.

Primary double reciprocal plots of the glutathionylspermidine synthetase reaction. Enzyme activity was determined as described under "Experimental Procedures." Each rate was determined from two different time points. The five fixed variable co-substrate concentrations were chosen as follows: 0.36 mM (bullet ), 0.47 mM (black-square), 0.66 mM (black-triangle), 1.11 mM (black-down-triangle ), and 3.57 mM (black-diamond ). A, the ATP concentration was varied from 0.10 to 0.66 mM at five fixed GSH concentrations. The spermidine concentration was kept constant at 0.47 mM. B, the GSH concentration was varied from 0.36 to 3.57 mM at five fixed spermidine concentrations. The ATP concentration was kept constant at 0.13 mM. C, the spermidine concentration was varied from 0.36 to 3.57 mM at five fixed GSH concentrations. The ATP concentration was kept constant at 0.13 mM.


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Table III. Dissociation constants and their S.D. values for the glutathionylspermidine synthetase

The dissociation constants are defined as KATP = [E][ATP]/[E · ATP], KGSH ATP = [E · GSH][ATP]/[E · GSH · ATP], etc. Limiting Km values correspond to the dissociation constants of the quarternary complexes (KGSH Sperm. ATP, etc.). In an ideal rapid equilibrium random mechanism, the four dissociation constants characterizing the affinity of a given substrate to the enzyme or its complexes should be identical. Pertinent experimental values are indeed not significantly different. The dissociation constants are defined as KATP = [E][ATP]/[E · ATP], KGSH ATP = [E · GSH][ATP]/[E · GSH · ATP], etc. Limiting Km values correspond to the dissociation constants of the quarternary complexes (KGSH Sperm. ATP, etc.). In an ideal rapid equilibrium random mechanism, the four dissociation constants characterizing the affinity of a given substrate to the enzyme or its complexes should be identical. Pertinent experimental values are indeed not significantly different.
Constant Value

mM
KATP 0.23  ± 0.07
KGSH ATP 0.35  ± 0.15
KSperm. ATP 0.17  ± 0.05
KGSH Sperm. ATP 0.26  ± 0.04
KGSH 1.47  ± 1.14
KATP GSH 1.84  ± 0.72
KSperm. GSH 1.78  ± 0.85
KATP Sperm. GSH 2.62  ± 0.79
KSperm. 0.45  ± 0.13
KATP Sperm. 0.34  ± 0.14
KGSH Sperm. 0.64  ± 0.24
KATP GSH Sperm. 0.47  ± 0.08


Fig. 8. Scheme of the glutathionylspermidine synthetase as a rapid equilibrium random terreactant system. For numerical values of dissociation constants see Table III.
[View Larger Version of this Image (21K GIF file)]

A quarternary complex mechanism implies that all three substrates must be assembled at the enzyme before a reaction can proceed. To check this hypothesis, we subjected the enzyme to long term exposure with Mg2+-ATP plus one of the additional substrates and monitored a potential partial reaction by 31P NMR. Fig. 9 demonstrates that with all combinations of substrates no ATP turnover could be observed within 5 h unless the third substrate was added. These findings strongly support the assumption of a quarternary complex mechanism and explain the absence of any ATPase activity of GspS. Neither can the presumed catalytic intermediate glutathionylphosphate be formed in any detectable amount by an incomplete catalytic complex.


Fig. 9. 31P NMR spectra during the reaction of the glutathionylspermidine synthetase with its substrates. A, GspS in the presence of ATP; incubation time = 0 min, scanning time = 7 min. B, GspS in the presence of ATP; incubation time = 5 h, scanning time = 30 min. C, the addition of the second substrate (GSH or spermidine); incubation time = 5 h, scanning time = 30 min. D, the addition of the third substrate (GSH or spermidine); incubation time = 5 h, scanning time = 30 min. Peak 1, inorganic phosphate; peak 2, ATP gamma -phosphate; peak 3, ADP beta -phosphate; peak 4, ADP alpha -phosphate; peak 5, ATP alpha -phosphate; peak 6, ATP beta -phosphate.
[View Larger Version of this Image (19K GIF file)]

As already mentioned, ADP significantly inhibits GspS, which renders it difficult to measure GspS activity in the absence of an ATP-regenerating system. The type of inhibition is competitive with respect to ATP (Fig. 6). A Ki of 80 µM was calculated, which is in the range of physiological ADP concentrations. GspS also proved to be feedback-inhibited by TSH with a Ki of 480 µM (Fig. 7), which is competed by GSH.


Fig. 6. Inhibition of glutathionylspermidine synthetase by ADP. Plot of enzyme-normalized reciprocal initial reaction velocities (e/v) versus concentrations of ADP. The concentrations of ATP were 0.25 mM (bullet ) and 0.75 mM (black-square), respectively.
[View Larger Version of this Image (11K GIF file)]


Fig. 7. Inhibition of glutathionylspermidine synthetase by trypanothione. Plot of enzyme-normalized reciprocal initial reaction velocities (e/v) versus concentrations of TSH. The concentrations of GSH were 2.5 mM (bullet ) and 10 mM (black-square), respectively.
[View Larger Version of this Image (11K GIF file)]


DISCUSSION

The purification scheme of GspS from C. fasciculata presented here allowed detailed functional analysis of the enzyme without interference from other enzymatic activities. The initial aqueous phase extraction procedures proved to be advantageous in separating the two enzymes involved in the synthesis of trypanothione into two different phases and in the complete separation of GspS from an ATPase activity present in the crude extract. We thereby implicitly confirmed that trypanothione biosynthesis of trypanosomatids, like the analogous GSH biosynthesis (33, 34), is achieved in two consecutive steps by two distinct proteins (1) and not by a single enzymatic entity as had been presumed formerly (22). In agreement with Smith et al. (1), we could not detect any trypanothione synthetase activity in our GspS preparation. A similar rapid equilibrium random mechanism as here established for GspS (Fig. 8) has already been described for GSH-synthesizing enzymes (33, 34). This kinetic pattern therefore appears not to be uncommon in nonribosomal amide-forming ligases.

Some characteristics of our GspS, however, differ from previous reports on this enzyme. Smith et al. (1) attributed a molecular mass of 90 kDa to GspS of C. fasciculata and 82 kDa to TS, whereas our GspS migrated in SDS and native gradient gels with an apparent molecular mass of 78 kDa. Clearly, the clarification of this discrepancy must await completion of full-length cDNA cloning to estimate the maximum size of GspS. Furthermore, Smith et al. (1) reported a sharp pH optimum at 6.5, whereas we found an optimum at about 7.5 and an inflection point of the pH dependence curve near 6.8, suggestive of a histidine residue participating in catalysis upon dissociation. Finally, a substantial rate of a partial reaction (i.e. spermidine-independent liberation of phosphate from ATP, presumed to result from the hydrolysis of the intermediate glutathionylphosphate) was reported for both GspS and TS of C. fasciculata (1). Any formation of an intermediate at a measurable rate and quantity would, however, hardly be compatible with the kinetic pattern of GspS worked out here. The deduced kinetic mechanism of GspS (i.e. a rapid equilibrium random quarternary complex mechanism) does not conflict with the assumption of an activation of GSH in the form of glutathionylphosphate during the transition state, but such a partial reaction would most likely require the assembly of all substrates at the active site. We also could experimentally rule out, in the absence of spermidine, any significant accumulation of glutathionylphosphate, which should have been detected by 31P NMR near 0.6 ppm after 5 h of incubation (Fig. 9). Yet neither an acylphosphate nor any ATP hydrolysis was observed unless all substrates were present.

Comparing GspS of C. fasciculata and E. coli reveals substantial differences. The limited sequence information of C. fasciculata so far available (see peptides reported and ongoing DNA sequencing) proves homology with the E. coli enzyme, but the extent of conserved residues appears to be restricted to about 40%. The divergence between the bacterial and the trypanosomal enzyme is obviously associated with pronounced functional diversification. Bollinger et al. (23, 24) reported a dual function for E. coli GspS, the Gsp synthetase activity and a Gsp amidase activity possibly residing in distinct domains of the protein. In concert, these two activities result in futile consumption of ATP without any meaningful anabolic outcome. The biological role of the E. coli Gsp synthetase/amidase is therefore discussed in the context of modulation of spermidine and/or GSH levels in response to growth conditions. In the GspS of C. fasciculata, despite its homology and comparable size, the amidase activity appears to have been lost during evolution. The influence of physiological effectors (i.e. product inhibition by ADP and feedback inhibition by TSH) classify the trypanosomatid GspS as a typical representative of the key enzymes of anabolic processes.

In conclusion, we have functionally and in part chemically characterized GspS, the key enzyme for the synthesis of TSH, which is believed to be the crucial mediator of the oxidant defense system in trypanosomatids (6). Trypanosomatid GspS does not exhibit any homology with known proteins in vertebrates and exhibits only limited similarity with the Gsp synthetase/amidase of E. coli. In view of the uniqueness of the protein and the widely discussed importance of TSH for trypanosomatid vitality and resistance to oxidant drugs, GspS might be considered as a potential target for a specific trypanocidal therapy. The convenient access to a stable partially purified enzyme preparation, the functional characterization, and the amino acid sequence data presented here should improve the basis for future developments to this end.


FOOTNOTES

*   The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
   To whom correspondence should be addressed: Dept. of Physiological Chemistry, Technical University of Braunschweig, Mascheroder Weg 1, D-38124 Braunschweig, Germany. Tel.: 49-531-6181599; Fax: 49-531-6181458.
1   The abbreviations used are: GspS, glutathionylspermidine synthetase; Gsp, glutathionylspermidine; TSH, trypanothione; TS, trypanothione synthetase; DTT, dithiothreitol; bis-Tris propane, 1,3-bis[tris(hydroxymethy)methylamino]propane; PEG, polyethylene glycol; PAGE, polyacrylamide gel electrophoresis; HPLC, high pressure liquid chromatography.

ACKNOWLEDGEMENTS

We thank Dr. Alan H. Fairlamb for the kind gift of the trypanosomatid C. fasciculata and advice on HPLC protocols. We thank Dr. Antonius Ross for help in fermentation, and we thank Kristin Anastassiadis and Rita Getzlaff for excellent technical assistance.


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